{"id":68,"date":"2013-04-26T16:51:07","date_gmt":"2013-04-26T16:51:07","guid":{"rendered":"https:\/\/sites.ifi.unicamp.br\/lpd\/?page_id=68"},"modified":"2019-07-23T13:23:39","modified_gmt":"2019-07-23T13:23:39","slug":"recent-publications","status":"publish","type":"page","link":"https:\/\/sites.ifi.unicamp.br\/lpd\/recent-publications\/","title":{"rendered":"Publications"},"content":{"rendered":"<p><div class=\"teachpress_pub_list\"><form name=\"tppublistform\" method=\"get\"><a name=\"tppubs\" id=\"tppubs\"><\/a><div class=\"tp_search_input\"><input name=\"tsr\" id=\"tp_search_input_field\" type=\"search\" placeholder=\"Enter search word\" value=\"\" tabindex=\"1\"\/><div class=\"teachpress_search_button\"><input name=\"tps_button\" class=\"tp_search_button\" type=\"submit\" tabindex=\"10\" value=\"Search\"\/><\/div><\/div><\/form><div class=\"tablenav\"><div class=\"tablenav-pages\"><span class=\"displaying-num\">105 entries<\/span> <a class=\"page-numbers button disabled\">&laquo;<\/a> <a class=\"page-numbers button disabled\">&lsaquo;<\/a> 1 of 6 <a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/recent-publications\/?limit=2&amp;tgid=&amp;yr=&amp;type=&amp;usr=&amp;auth=&amp;tsr=\" title=\"next page\" class=\"page-numbers button\">&rsaquo;<\/a> <a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/recent-publications\/?limit=6&amp;tgid=&amp;yr=&amp;type=&amp;usr=&amp;auth=&amp;tsr=\" title=\"last page\" class=\"page-numbers button\">&raquo;<\/a> <\/div><\/div><div class=\"teachpress_publication_list\"><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">1.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Carvalho, Nat\u00e1lia C;  Kersul, Cau\u00ea M;  Frateschi, Newton C;  Wiederhecker, Gustavo S;  Alegre, Thiago Mayer P<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('240','tp_links')\" style=\"cursor:pointer;\">Quasinormal-Mode Perturbation Theory for Dissipative and Dispersive Optomechanics<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Physical Review Letters, <\/span><span class=\"tp_pub_additional_volume\">vol. 125, <\/span><span class=\"tp_pub_additional_number\">no. 23, <\/span><span class=\"tp_pub_additional_pages\">pp. 233601, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 0031-9007<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_240\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('240','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_240\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('240','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_240\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('240','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_240\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{primo2020dissipative,<br \/>\r\ntitle = {Quasinormal-Mode Perturbation Theory for Dissipative and Dispersive Optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Nat\u00e1lia C Carvalho and Cau{\u00ea} M Kersul and Newton C Frateschi and Gustavo S Wiederhecker and Thiago Mayer P Alegre},<br \/>\r\nurl = {http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125.233601},<br \/>\r\ndoi = {10.1103\/PhysRevLett.125.233601},<br \/>\r\nissn = {0031-9007},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-12-01},<br \/>\r\njournal = {Physical Review Letters},<br \/>\r\nvolume = {125},<br \/>\r\nnumber = {23},<br \/>\r\npages = {233601},<br \/>\r\nabstract = {Despite the several novel features arising from the dissipative optomechanical coupling, such effect remains vastly unexplored due to the lack of a simple formalism that captures non-Hermiticity in optomechanical systems. In this Letter, we show that quasinormal-mode-based perturbation theory is capable of correctly predicting both dispersive and dissipative optomechanical couplings. We validate our model through simulations and also by comparison with experimental results reported in the literature. Finally, we apply this formalism to plasmonic systems, used for molecular optomechanics, where strong dissipative coupling signatures in the amplification of vibrational modes are observed.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('240','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_240\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Despite the several novel features arising from the dissipative optomechanical coupling, such effect remains vastly unexplored due to the lack of a simple formalism that captures non-Hermiticity in optomechanical systems. In this Letter, we show that quasinormal-mode-based perturbation theory is capable of correctly predicting both dispersive and dissipative optomechanical couplings. We validate our model through simulations and also by comparison with experimental results reported in the literature. Finally, we apply this formalism to plasmonic systems, used for molecular optomechanics, where strong dissipative coupling signatures in the amplification of vibrational modes are observed.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('240','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_240\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-arxiv\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125.233601\" title=\"http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125[...]\" target=\"_blank\">http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1103\/PhysRevLett.125.233601\" title=\"Follow DOI:10.1103\/PhysRevLett.125.233601\" target=\"_blank\">doi:10.1103\/PhysRevLett.125.233601<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('240','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">2.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Inga, Marvyn;  Fujii, La\u00eds; da Silva Filho, Jos\u00e9 Maria C;  Palhares, Jo\u00e3o Henrique Quintino;  Ferlauto, Andre Santarosa;  Marques, Francisco C;  Alegre, Thiago P Mayer;  Wiederhecker, Gustavo<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('241','tp_links')\" style=\"cursor:pointer;\">Alumina coating for dispersion management in ultra-high Q microresonators<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">APL Photonics, <\/span><span class=\"tp_pub_additional_volume\">vol. 5, <\/span><span class=\"tp_pub_additional_number\">no. 11, <\/span><span class=\"tp_pub_additional_pages\">pp. 116107, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2378-0967<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_resource_link\"><a id=\"tp_links_sh_241\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('241','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_241\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('241','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_241\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Inga2020,<br \/>\r\ntitle = {Alumina coating for dispersion management in ultra-high Q microresonators},<br \/>\r\nauthor = {Marvyn Inga and La\u00eds Fujii and Jos\u00e9 Maria C {da Silva Filho} and Jo{\u00e3}o Henrique {Quintino Palhares} and Andre Santarosa Ferlauto and Francisco C Marques and Thiago P {Mayer Alegre} and Gustavo Wiederhecker},<br \/>\r\nurl = {http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839},<br \/>\r\ndoi = {10.1063\/5.0028839},<br \/>\r\nissn = {2378-0967},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-11-01},<br \/>\r\njournal = {APL Photonics},<br \/>\r\nvolume = {5},<br \/>\r\nnumber = {11},<br \/>\r\npages = {116107},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('241','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_241\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839\" title=\"http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839\" target=\"_blank\">http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1063\/5.0028839\" title=\"Follow DOI:10.1063\/5.0028839\" target=\"_blank\">doi:10.1063\/5.0028839<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('241','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">3.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Li, Jie;  Wallucks, Andreas;  Benevides, Rodrigo;  Fiaschi, Niccolo;  Hensen, Bas;  Alegre, Thiago Mayer P;  Gr\u00f6blacher, Simon<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('242','tp_links')\" style=\"cursor:pointer;\">Proposal for optomechanical quantum teleportation<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Physical Review A, <\/span><span class=\"tp_pub_additional_volume\">vol. 102, <\/span><span class=\"tp_pub_additional_number\">no. 3, <\/span><span class=\"tp_pub_additional_pages\">pp. 032402, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2469-9926<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_242\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('242','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_242\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('242','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_242\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('242','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_242\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{li2020proposal,<br \/>\r\ntitle = {Proposal for optomechanical quantum teleportation},<br \/>\r\nauthor = {Jie Li and Andreas Wallucks and Rodrigo Benevides and Niccolo Fiaschi and Bas Hensen and Thiago Mayer P Alegre and Simon Gr\u00f6blacher},<br \/>\r\nurl = {http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevA.102.032402},<br \/>\r\ndoi = {10.1103\/PhysRevA.102.032402},<br \/>\r\nissn = {2469-9926},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-09-01},<br \/>\r\njournal = {Physical Review A},<br \/>\r\nvolume = {102},<br \/>\r\nnumber = {3},<br \/>\r\npages = {032402},<br \/>\r\nabstract = {We present a novel discrete-variable quantum teleportation scheme using pulsed optomechanics. In our proposal, we demonstrate how an unknown optical input state can be transferred onto the joint state of a pair of mechanical oscillators, without physically interacting with one another. We further analyze how experimental imperfections will affect the fidelity of the teleportation and highlight how our scheme can be realized in current state-of-the-art optomechanical systems.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('242','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_242\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We present a novel discrete-variable quantum teleportation scheme using pulsed optomechanics. In our proposal, we demonstrate how an unknown optical input state can be transferred onto the joint state of a pair of mechanical oscillators, without physically interacting with one another. We further analyze how experimental imperfections will affect the fidelity of the teleportation and highlight how our scheme can be realized in current state-of-the-art optomechanical systems.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('242','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_242\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-arxiv\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevA.102.032402\" title=\"http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 ht[...]\" target=\"_blank\">http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 ht[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402\" title=\"Follow DOI:10.1103\/PhysRevA.102.032402\" target=\"_blank\">doi:10.1103\/PhysRevA.102.032402<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('242','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">4.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Fujii, L;  Inga, M;  Soares, J H;  Espinel, Y A V;  Alegre, T P Mayer;  Wiederhecker, G S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('231','tp_links')\" style=\"cursor:pointer;\">Dispersion tailoring in wedge microcavities for Kerr comb generation<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Optics Letters, <\/span><span class=\"tp_pub_additional_volume\">vol. 45, <\/span><span class=\"tp_pub_additional_number\">no. 12, <\/span><span class=\"tp_pub_additional_pages\">pp. 3232, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 0146-9592<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_231\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('231','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_231\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('231','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_231\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('231','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_231\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Fujii2020,<br \/>\r\ntitle = {Dispersion tailoring in wedge microcavities for Kerr comb generation},<br \/>\r\nauthor = {L Fujii and M Inga and J H Soares and Y A V Espinel and T P {Mayer Alegre} and G S Wiederhecker},<br \/>\r\nurl = {https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232},<br \/>\r\ndoi = {10.1364\/ol.393294},<br \/>\r\nissn = {0146-9592},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-06-01},<br \/>\r\njournal = {Optics Letters},<br \/>\r\nvolume = {45},<br \/>\r\nnumber = {12},<br \/>\r\npages = {3232},<br \/>\r\nabstract = {The shaping of group velocity dispersion in microresonators is an important component in the generation of wideband optical frequency combs. Small resonators - with tight bending radii - offer the large free-spectral range desirable for wide comb formation. However, the tighter bending usually limit comb formation as it enhances normal group velocity dispersion. We experimentally demonstrate that engineering the sidewall angle of small-radius (100 $mu$m), 3 $mu$m-thick silica wedge microdisks enables dispersion tuning in both normal and anomalous regimes, without significantly affecting the free spectral range. A microdisk with wedge angle of $55^circ$ (anomalous dispersion) is used to demonstrate a 300 nm bandwidth Kerr optical frequency comb.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('231','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_231\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The shaping of group velocity dispersion in microresonators is an important component in the generation of wideband optical frequency combs. Small resonators - with tight bending radii - offer the large free-spectral range desirable for wide comb formation. However, the tighter bending usually limit comb formation as it enhances normal group velocity dispersion. We experimentally demonstrate that engineering the sidewall angle of small-radius (100 $mu$m), 3 $mu$m-thick silica wedge microdisks enables dispersion tuning in both normal and anomalous regimes, without significantly affecting the free spectral range. A microdisk with wedge angle of $55^circ$ (anomalous dispersion) is used to demonstrate a 300 nm bandwidth Kerr optical frequency comb.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('231','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_231\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232\" title=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232\" target=\"_blank\">https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/ol.393294\" title=\"Follow DOI:10.1364\/ol.393294\" target=\"_blank\">doi:10.1364\/ol.393294<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('231','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">5.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Melo, Emerson G;  Ribeiro, Ana L A;  Benevides, Rodrigo S;  Zuben, Antonio A G V; dos Santos, Marcos V Puydinger;  Silva, Alexandre A;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('232','tp_links')\" style=\"cursor:pointer;\">Bright and Vivid Diffractive\u2013Plasmonic Reflective Filters for Color Generation<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">ACS Applied Nano Materials, <\/span><span class=\"tp_pub_additional_volume\">vol. 3, <\/span><span class=\"tp_pub_additional_number\">no. 2, <\/span><span class=\"tp_pub_additional_pages\">pp. 1111\u20131117, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2574-0970<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_232\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('232','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_232\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('232','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_232\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('232','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_232\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Melo2020,<br \/>\r\ntitle = {Bright and Vivid Diffractive\u2013Plasmonic Reflective Filters for Color Generation},<br \/>\r\nauthor = {Emerson G Melo and Ana L A Ribeiro and Rodrigo S Benevides and Antonio A G V Zuben and Marcos V {Puydinger dos Santos} and Alexandre A Silva and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508},<br \/>\r\ndoi = {10.1021\/acsanm.9b02508},<br \/>\r\nissn = {2574-0970},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-02-01},<br \/>\r\njournal = {ACS Applied Nano Materials},<br \/>\r\nvolume = {3},<br \/>\r\nnumber = {2},<br \/>\r\npages = {1111--1117},<br \/>\r\nabstract = {The desire to reproduce vivid colors such as those found in birds, fishes, flowers, and insects has driven extensive research into nanostructured surfaces especially because of their high spatial resolution. Using a periodic silicon-patterned structure coated with aluminum, we combine two distinct and yet interconnected effects to produce bright and vivid color surfaces. A genetic algorithm optimization process was used to fine-tune both the diffraction and plasmonic effects to obtain reflective color filters for the red, green, and blue colors. The obtained structures are suitable for displays, image applications, color sensors, and optical filters.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('232','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_232\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The desire to reproduce vivid colors such as those found in birds, fishes, flowers, and insects has driven extensive research into nanostructured surfaces especially because of their high spatial resolution. Using a periodic silicon-patterned structure coated with aluminum, we combine two distinct and yet interconnected effects to produce bright and vivid color surfaces. A genetic algorithm optimization process was used to fine-tune both the diffraction and plasmonic effects to obtain reflective color filters for the red, green, and blue colors. The obtained structures are suitable for displays, image applications, color sensors, and optical filters.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('232','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_232\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508\" title=\"https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508\" target=\"_blank\">https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1021\/acsanm.9b02508\" title=\"Follow DOI:10.1021\/acsanm.9b02508\" target=\"_blank\">doi:10.1021\/acsanm.9b02508<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('232','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">6.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Benevides, Rodrigo;  Kersul, Cau\u00ea M; de Assis, Pierre-Louis;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('248','tp_links')\" style=\"cursor:pointer;\">Thermodynamic model for photothermal effects in optomechanics<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STh1R.6, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_248\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('248','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_248\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('248','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_248\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('248','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_248\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Primo2020a,<br \/>\r\ntitle = {Thermodynamic model for photothermal effects in optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Rodrigo Benevides and Cau{\u00ea} M Kersul and Pierre-Louis de Assis and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2020.STh1R.6},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STh1R.6},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We derive and validate a model for the photothermal forces that act on optomechanical cavities. Our results not only enable the prediction of such effect but also show that it is much stronger than previously estimated.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('248','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_248\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We derive and validate a model for the photothermal forces that act on optomechanical cavities. Our results not only enable the prediction of such effect but also show that it is much stronger than previously estimated.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('248','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_248\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.o[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.o[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2020.STh1R.6\" title=\"Follow DOI:10.1364\/CLEO_SI.2020.STh1R.6\" target=\"_blank\">doi:10.1364\/CLEO_SI.2020.STh1R.6<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('248','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">7.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Inga, Marvyn; dos Santos, Lais Fujii; da Silva Filho, Jose M C;  Espinel, Y A V;  Marques, Francisco C;  Alegre, Thiago P M;  Wiederhecker, Gustavo S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('247','tp_links')\" style=\"cursor:pointer;\">Tailoring group-velocity dispersion in microspheres with alumina coating<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JTh2C.4, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_247\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('247','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_247\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('247','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_247\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('247','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_247\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Inga2020b,<br \/>\r\ntitle = {Tailoring group-velocity dispersion in microspheres with alumina coating},<br \/>\r\nauthor = {Marvyn Inga and Lais Fujii dos Santos and Jose M C {da Silva Filho} and Y A V Espinel and Francisco C Marques and Thiago P M Alegre and Gustavo S Wiederhecker},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JTh2C.4},<br \/>\r\ndoi = {10.1364\/CLEO_AT.2020.JTh2C.4},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JTh2C.4},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We experimentally demonstrate that the group-velocity dispersion of silica microspheres can be engineered by coating it with nanometer-thick layers of alumina (Al2O3). The ultra-high optical quality factor (&gt; 107) achieved allows for the generation of optical frequency combs.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('247','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_247\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We experimentally demonstrate that the group-velocity dispersion of silica microspheres can be engineered by coating it with nanometer-thick layers of alumina (Al2O3). The ultra-high optical quality factor (&gt; 107) achieved allows for the generation of optical frequency combs.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('247','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_247\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JTh2C.4\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_AT.2020.JTh2C.4\" title=\"Follow DOI:10.1364\/CLEO_AT.2020.JTh2C.4\" target=\"_blank\">doi:10.1364\/CLEO_AT.2020.JTh2C.4<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('247','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">8.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\">de Oliveira Zurita, Roberto;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('246','tp_links')\" style=\"cursor:pointer;\">Strong confinement of short-wave Brillouin phonons in silicon waveguide periodic lattices<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. FTh3C.2, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_246\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('246','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_246\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('246','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_246\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('246','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_246\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{DeOliveiraZurita2020,<br \/>\r\ntitle = {Strong confinement of short-wave Brillouin phonons in silicon waveguide periodic lattices},<br \/>\r\nauthor = {Roberto {de Oliveira Zurita} and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2},<br \/>\r\ndoi = {10.1364\/CLEO_QELS.2020.FTh3C.2},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {FTh3C.2},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We propose a feasible silicon waveguide design that can strongly trap short-wavelength Brillouin phonons. Intramodal backward Brillouin gain is improved about 4.3 while radiation losses are suppressed. The structure could be implemented using SOI technology.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('246','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_246\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We propose a feasible silicon waveguide design that can strongly trap short-wavelength Brillouin phonons. Intramodal backward Brillouin gain is improved about 4.3 while radiation losses are suppressed. The structure could be implemented using SOI technology.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('246','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_246\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_QELS.2020.FTh3C.2\" title=\"Follow DOI:10.1364\/CLEO_QELS.2020.FTh3C.2\" target=\"_blank\">doi:10.1364\/CLEO_QELS.2020.FTh3C.2<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('246','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">9.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Carvalho, Natalia C;  Kersul, Cau\u00ea M;  Wiederhecker, Gustavo S;  Frateschi, Newton C;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('245','tp_links')\" style=\"cursor:pointer;\">Non-Hermitian Optomechanics<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. FTh3C.3, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_245\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('245','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_245\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('245','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_245\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('245','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_245\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Primo2020b,<br \/>\r\ntitle = {Non-Hermitian Optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Natalia C Carvalho and Cau{\u00ea} M Kersul and Gustavo S Wiederhecker and Newton C Frateschi and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3},<br \/>\r\ndoi = {10.1364\/CLEO_QELS.2020.FTh3C.3},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {FTh3C.3},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We propose and numerically validate a modified perturbation theory that captures non-Hermitian features present in dissipative optomechanical systems. Our theory predicts different behaviors than commonly used perturbation theories derived assuming purely Hermitian dynamics.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('245','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_245\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We propose and numerically validate a modified perturbation theory that captures non-Hermitian features present in dissipative optomechanical systems. Our theory predicts different behaviors than commonly used perturbation theories derived assuming purely Hermitian dynamics.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('245','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_245\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_QELS.2020.FTh3C.3\" title=\"Follow DOI:10.1364\/CLEO_QELS.2020.FTh3C.3\" target=\"_blank\">doi:10.1364\/CLEO_QELS.2020.FTh3C.3<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('245','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">10.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Rodrigues, Caique C;  Kersul, Caue M;  Lipson, Michal;  Alegre, Thiago P M;  Wiederhecker, Gustavo S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('244','tp_links')\" style=\"cursor:pointer;\">High-Harmonic Synchronization of Optomechanical Oscillators<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JW2B.27, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_244\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('244','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_244\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('244','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_244\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('244','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_244\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Rodrigues2020,<br \/>\r\ntitle = {High-Harmonic Synchronization of Optomechanical Oscillators},<br \/>\r\nauthor = {Caique C Rodrigues and Caue M Kersul and Michal Lipson and Thiago P M Alegre and Gustavo S Wiederhecker},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27},<br \/>\r\ndoi = {10.1364\/CLEO_AT.2020.JW2B.27},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JW2B.27},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We experimentally demonstrate injection locking of an optomechanical oscillator driven at multiple harmonics of its fundamental frequency. The measured Arnold tongues show strongest synchronization when driven at even harmonics.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('244','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_244\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We experimentally demonstrate injection locking of an optomechanical oscillator driven at multiple harmonics of its fundamental frequency. The measured Arnold tongues show strongest synchronization when driven at even harmonics.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('244','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_244\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.o[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.o[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_AT.2020.JW2B.27\" title=\"Follow DOI:10.1364\/CLEO_AT.2020.JW2B.27\" target=\"_blank\">doi:10.1364\/CLEO_AT.2020.JW2B.27<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('244','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">11.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Carvalho, Natalia C;  Benevides, Rodrigo;  M\u00e9nard, Micha\u00ebl;  Wiederhecker, Gustavo S;  Frateschi, Newton C;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('243','tp_links')\" style=\"cursor:pointer;\">High-frequency GaAs bullseye optomechanical resonator<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STh1R.5, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_243\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('243','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_243\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('243','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_243\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('243','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_243\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Carvalho2020,<br \/>\r\ntitle = {High-frequency GaAs bullseye optomechanical resonator},<br \/>\r\nauthor = {Natalia C Carvalho and Rodrigo Benevides and Micha{\u00eb}l M\u00e9nard and Gustavo S Wiederhecker and Newton C Frateschi and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2020.STh1R.5},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STh1R.5},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We fabricated and measured a GaAs bullseye resonator able to operate above 3 GHz when coupled to whispering gallery optical modes. Our large phononic bandgap allowed us to observe the symmetry break caused by the material anisotropy and obtain optomechanical coupling rates above 30 kHz.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('243','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_243\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We fabricated and measured a GaAs bullseye resonator able to operate above 3 GHz when coupled to whispering gallery optical modes. Our large phononic bandgap allowed us to observe the symmetry break caused by the material anisotropy and obtain optomechanical coupling rates above 30 kHz.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('243','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_243\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.o[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.o[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2020.STh1R.5\" title=\"Follow DOI:10.1364\/CLEO_SI.2020.STh1R.5\" target=\"_blank\">doi:10.1364\/CLEO_SI.2020.STh1R.5<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('243','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">12.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Benevides, Rodrigo;  M\u00e9nard, Micha\u00ebl;  Wiederhecker, Gustavo S;  Alegre, Thiago P Mayer<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('230','tp_links')\" style=\"cursor:pointer;\"> Ar\/Cl 2 etching of GaAs optomechanical microdisks fabricated with positive electroresist <\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Optical Materials Express, <\/span><span class=\"tp_pub_additional_volume\">vol. 10, <\/span><span class=\"tp_pub_additional_number\">no. 1, <\/span><span class=\"tp_pub_additional_pages\">pp. 57, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2159-3930<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_230\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('230','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_230\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('230','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_230\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('230','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_230\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Benevides2020,<br \/>\r\ntitle = { Ar\/Cl 2 etching of GaAs optomechanical microdisks fabricated with positive electroresist },<br \/>\r\nauthor = {Rodrigo Benevides and Micha{\u00eb}l M\u00e9nard and Gustavo S Wiederhecker and Thiago P {Mayer Alegre}},<br \/>\r\nurl = {https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57},<br \/>\r\ndoi = {10.1364\/OME.10.000057},<br \/>\r\nissn = {2159-3930},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\njournal = {Optical Materials Express},<br \/>\r\nvolume = {10},<br \/>\r\nnumber = {1},<br \/>\r\npages = {57},<br \/>\r\nabstract = {A method to fabricate GaAs microcavities using only a soft mask with an electrolithographic pattern in an inductively coupled plasma etching is presented. A careful characterization of the fabrication process pinpointing the main routes for a smooth device sidewall is discussed. Using the final recipe, optomechanical microdisk resonators are fabricated. The results show a very high optical quality factors of $Q_textopt&gt;2times 10^5$, among the largest already reported for dry-etching devices. The final devices are also shown to present high mechanical quality factors and an optomechanical vacuum coupling constant of $g_0=2pitimes 13.6$ kHz enabling self-sustainable mechanical oscillations for an optical input power above $1$ mW.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('230','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_230\" style=\"display:none;\"><div class=\"tp_abstract_entry\">A method to fabricate GaAs microcavities using only a soft mask with an electrolithographic pattern in an inductively coupled plasma etching is presented. A careful characterization of the fabrication process pinpointing the main routes for a smooth device sidewall is discussed. Using the final recipe, optomechanical microdisk resonators are fabricated. The results show a very high optical quality factors of $Q_textopt&gt;2times 10^5$, among the largest already reported for dry-etching devices. The final devices are also shown to present high mechanical quality factors and an optomechanical vacuum coupling constant of $g_0=2pitimes 13.6$ kHz enabling self-sustainable mechanical oscillations for an optical input power above $1$ mW.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('230','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_230\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57\" title=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57\" target=\"_blank\">https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OME.10.000057\" title=\"Follow DOI:10.1364\/OME.10.000057\" target=\"_blank\">doi:10.1364\/OME.10.000057<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('230','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">13.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Benevides, Rodrigo;  Kersul, Cau\u00ea M; de Assis, Pierre-Louis;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('233','tp_links')\" style=\"cursor:pointer;\">Modelling bolometric backaction in cavity optomechanics<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Frontiers in Optics $+$ Laser Science APS\/DLS, <\/span><span class=\"tp_pub_additional_pages\">pp. JTu3A.87, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2019<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_233\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('233','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_233\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('233','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_233\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('233','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_233\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Primo:19,<br \/>\r\ntitle = {Modelling bolometric backaction in cavity optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Rodrigo Benevides and Cau\u00ea M Kersul and Pierre-Louis de Assis and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87},<br \/>\r\ndoi = {10.1364\/FIO.2019.JTu3A.87},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\nbooktitle = {Frontiers in Optics $+$ Laser Science APS\/DLS},<br \/>\r\njournal = {Frontiers in Optics $+$ Laser Science APS\/DLS},<br \/>\r\npages = {JTu3A.87},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {From thermodynamic considerations we derive a model for thermally driven stresses that induce changes on acoustic dynamics, enabling the engineering of devices where these effects are suppressed or enhanced when compared to optomechanical backaction.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('233','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_233\" style=\"display:none;\"><div class=\"tp_abstract_entry\">From thermodynamic considerations we derive a model for thermally driven stresses that induce changes on acoustic dynamics, enabling the engineering of devices where these effects are suppressed or enhanced when compared to optomechanical backaction.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('233','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_233\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/FIO.2019.JTu3A.87\" title=\"Follow DOI:10.1364\/FIO.2019.JTu3A.87\" target=\"_blank\">doi:10.1364\/FIO.2019.JTu3A.87<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('233','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_techreport\"><div class=\"tp_pub_number\">14.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Wiederhecker, Gustavo;  Dainese, Paulo;  Alegre, Thiago P Mayer<\/p><p class=\"tp_pub_title\"><a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/data-and-simulations-files-for-the-tutorial-article\/\">Data and simulations files for the tutorial article <\/a> <span class=\"tp_pub_type tp_  techreport\">Technical Report<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_year\">2019<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_226\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('226','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_226\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('226','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_226\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('226','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_226\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@techreport{Wiederhecker:2019bq,<br \/>\r\ntitle = {Data and simulations files for the tutorial article },<br \/>\r\nauthor = {Gustavo Wiederhecker and Paulo Dainese and Thiago P Mayer Alegre},<br \/>\r\nurl = {https:\/\/zenodo.org\/record\/1971811},<br \/>\r\ndoi = {10.5281\/zenodo.1971811},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\nabstract = {Data and simulations files for the tutorial article \"Brillouin optomechanics in nanophotonic structures\". Published in APL Photonics Special issue \u00d6ptoacoustics\u2014Advances in high-frequency optomechanics and Brillouin scattering\" - DOI: 10.1063\/1.5088169},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {techreport}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('226','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_226\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Data and simulations files for the tutorial article &quot;Brillouin optomechanics in nanophotonic structures&quot;. Published in APL Photonics Special issue \u00d6ptoacoustics\u2014Advances in high-frequency optomechanics and Brillouin scattering&quot; - DOI: 10.1063\/1.5088169<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('226','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_226\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/zenodo.org\/record\/1971811\" title=\"https:\/\/zenodo.org\/record\/1971811\" target=\"_blank\">https:\/\/zenodo.org\/record\/1971811<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.5281\/zenodo.1971811\" title=\"Follow DOI:10.5281\/zenodo.1971811\" target=\"_blank\">doi:10.5281\/zenodo.1971811<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('226','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">15.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Wiederhecker, Gustavo S;  Dainese, Paulo;  Alegre, Thiago Mayer P<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('225','tp_links')\" style=\"cursor:pointer;\">Brillouin optomechanics in nanophotonic structures<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">APL Photonic, <\/span><span class=\"tp_pub_additional_volume\">vol. 4, <\/span><span class=\"tp_pub_additional_number\">no. 7, <\/span><span class=\"tp_pub_additional_pages\">pp. 071101, <\/span><span class=\"tp_pub_additional_year\">2019<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_225\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('225','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_225\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('225','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_225\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('225','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_225\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Wiederhecker:2019ey,<br \/>\r\ntitle = {Brillouin optomechanics in nanophotonic structures},<br \/>\r\nauthor = {Gustavo S Wiederhecker and Paulo Dainese and Thiago Mayer P Alegre},<br \/>\r\nurl = {http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169},<br \/>\r\ndoi = {10.1063\/1.5088169},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\njournal = {APL Photonic},<br \/>\r\nvolume = {4},<br \/>\r\nnumber = {7},<br \/>\r\npages = {071101},<br \/>\r\npublisher = {AIP Publishing LLC},<br \/>\r\nabstract = {The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary effects\u2014interplay to foster exciting possibilities in this field. In order to stimulate beginners into this growing research field, this tutorial is accompanied by all the discussed simulation material based on a widespread commercial finite-element solver.The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary ef...},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('225','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_225\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary effects\u2014interplay to foster exciting possibilities in this field. In order to stimulate beginners into this growing research field, this tutorial is accompanied by all the discussed simulation material based on a widespread commercial finite-element solver.The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary ef...<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('225','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_225\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169\" title=\"http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169\" target=\"_blank\">http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1063\/1.5088169\" title=\"Follow DOI:10.1063\/1.5088169\" target=\"_blank\">doi:10.1063\/1.5088169<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('225','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">16.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Barnard, Arthur W;  Zhang, Mian;  Wiederhecker, Gustavo S;  Lipson, Michal;  McEuen, Paul L<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('224','tp_links')\" style=\"cursor:pointer;\">Real-time vibrations of a carbon nanotube<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Nature, <\/span><span class=\"tp_pub_additional_volume\">vol. 566, <\/span><span class=\"tp_pub_additional_number\">no. 7742, <\/span><span class=\"tp_pub_additional_pages\">pp. 89\u201393, <\/span><span class=\"tp_pub_additional_year\">2019<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 1476-4687<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_224\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('224','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_224\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('224','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_224\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('224','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_224\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Barnard:2019aa,<br \/>\r\ntitle = {Real-time vibrations of a carbon nanotube},<br \/>\r\nauthor = {Arthur W Barnard and Mian Zhang and Gustavo S Wiederhecker and Michal Lipson and Paul L McEuen},<br \/>\r\nurl = {https:\/\/doi.org\/10.1038\/s41586-018-0861-0},<br \/>\r\ndoi = {10.1038\/s41586-018-0861-0},<br \/>\r\nisbn = {1476-4687},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\njournal = {Nature},<br \/>\r\nvolume = {566},<br \/>\r\nnumber = {7742},<br \/>\r\npages = {89--93},<br \/>\r\nabstract = {The field of miniature mechanical oscillators is rapidly evolving, with emerging applications including signal processing, biological detection1 and fundamental tests of quantum mechanics2. As the dimensions of a mechanical oscillator shrink to the molecular scale, such as in a carbon nanotube resonator3--7, their vibrations become increasingly coupled and strongly interacting8,9 until even weak thermal fluctuations could make the oscillator nonlinear10--13. The mechanics at this scale possesses rich dynamics, unexplored because an efficient way of detecting the motion in real time is lacking. Here we directly measure the thermal vibrations of a carbon nanotube in real time using a high-finesse micrometre-scale silicon nitride optical cavity as a sensitive photonic microscope. With the high displacement sensitivity of 700 fm Hz\u22121\/2 and the fine time resolution of this technique, we were able to discover a realm of dynamics undetected by previous time-averaged measurements and a room-temperature coherence that is nearly three orders of magnitude longer than previously reported. We find that the discrepancy in the coherence stems from long-time non-equilibrium dynamics, analogous to the Fermi--Pasta--Ulam--Tsingou recurrence seen in nonlinear systems14. Our data unveil the emergence of a weakly chaotic mechanical breather15, in which vibrational energy is recurrently shared among several resonance modes---dynamics that we are able to reproduce using a simple numerical model. These experiments open up the study of nonlinear mechanical systems in the Brownian limit (that is, when a system is driven solely by thermal fluctuations) and present an integrated, sensitive, high-bandwidth nanophotonic interface for carbon nanotube resonators.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('224','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_224\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The field of miniature mechanical oscillators is rapidly evolving, with emerging applications including signal processing, biological detection1 and fundamental tests of quantum mechanics2. As the dimensions of a mechanical oscillator shrink to the molecular scale, such as in a carbon nanotube resonator3--7, their vibrations become increasingly coupled and strongly interacting8,9 until even weak thermal fluctuations could make the oscillator nonlinear10--13. The mechanics at this scale possesses rich dynamics, unexplored because an efficient way of detecting the motion in real time is lacking. Here we directly measure the thermal vibrations of a carbon nanotube in real time using a high-finesse micrometre-scale silicon nitride optical cavity as a sensitive photonic microscope. With the high displacement sensitivity of 700 fm Hz\u22121\/2 and the fine time resolution of this technique, we were able to discover a realm of dynamics undetected by previous time-averaged measurements and a room-temperature coherence that is nearly three orders of magnitude longer than previously reported. We find that the discrepancy in the coherence stems from long-time non-equilibrium dynamics, analogous to the Fermi--Pasta--Ulam--Tsingou recurrence seen in nonlinear systems14. Our data unveil the emergence of a weakly chaotic mechanical breather15, in which vibrational energy is recurrently shared among several resonance modes---dynamics that we are able to reproduce using a simple numerical model. These experiments open up the study of nonlinear mechanical systems in the Brownian limit (that is, when a system is driven solely by thermal fluctuations) and present an integrated, sensitive, high-bandwidth nanophotonic interface for carbon nanotube resonators.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('224','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_224\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/doi.org\/10.1038\/s41586-018-0861-0\" title=\"https:\/\/doi.org\/10.1038\/s41586-018-0861-0\" target=\"_blank\">https:\/\/doi.org\/10.1038\/s41586-018-0861-0<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1038\/s41586-018-0861-0\" title=\"Follow DOI:10.1038\/s41586-018-0861-0\" target=\"_blank\">doi:10.1038\/s41586-018-0861-0<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('224','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">17.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Princepe, Debora;  Wiederhecker, Gustavo S;  Favero, Ivan;  Frateschi, Newton C<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('207','tp_links')\" style=\"cursor:pointer;\">Self-Sustained Laser Pulsation in Active Optomechanical Devices<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">IEEE PHOTONICS JOURNAL, <\/span><span class=\"tp_pub_additional_volume\">vol. 10, <\/span><span class=\"tp_pub_additional_number\">no. 3, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 1943-0655<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_207\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('207','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_207\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('207','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_207\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('207','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_207\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{ISI:000432841700001,<br \/>\r\ntitle = {Self-Sustained Laser Pulsation in Active Optomechanical Devices},<br \/>\r\nauthor = {Debora Princepe and Gustavo S Wiederhecker and Ivan Favero and Newton C Frateschi},<br \/>\r\ndoi = {10.1109\/JPHOT.2018.2831001},<br \/>\r\nissn = {1943-0655},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-06-01},<br \/>\r\njournal = {IEEE PHOTONICS JOURNAL},<br \/>\r\nvolume = {10},<br \/>\r\nnumber = {3},<br \/>\r\npublisher = {IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC},<br \/>\r\naddress = {445 HOES LANE, PISCATAWAY, NJ 08855-4141 USA},<br \/>\r\nabstract = {We developed a model for an active optomechanical cavity embedding a <br \/>\r\n semiconductor optical gain medium in the presence of dispersive and <br \/>\r\n dissipative optomechanical couplings. Radiation pressure drives the <br \/>\r\n mechanical oscillation and the back-action occurs due to the mechanical <br \/>\r\n modulation of the cavity loss rate. Our numerical analysis utilizing <br \/>\r\n this model shows that, even in a wideband gain material, such mechanism <br \/>\r\n couples the mechanical vibration with the laser relaxation oscillation, <br \/>\r\n enabling an effect of self-pulsed laser emission. In order to <br \/>\r\n investigate this effect, we propose a bullseye-shaped device with high <br \/>\r\n confinement of both the optical and the mechanical modes at the edge of <br \/>\r\n a disk combined with a dissipative structure in its vicinity. The <br \/>\r\n dispersive interaction is promoted by the strong photoelastic effect <br \/>\r\n while the dissipative mechanism is governed by the boundary motion <br \/>\r\n mechanism, enhanced by near-field interaction with the absorptive <br \/>\r\n structure. This hybrid optomechanical device is shown to lead sufficient <br \/>\r\n coupling for the experimental demonstration of the self-pulsed emission.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('207','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_207\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We developed a model for an active optomechanical cavity embedding a <br \/>\r\n semiconductor optical gain medium in the presence of dispersive and <br \/>\r\n dissipative optomechanical couplings. Radiation pressure drives the <br \/>\r\n mechanical oscillation and the back-action occurs due to the mechanical <br \/>\r\n modulation of the cavity loss rate. Our numerical analysis utilizing <br \/>\r\n this model shows that, even in a wideband gain material, such mechanism <br \/>\r\n couples the mechanical vibration with the laser relaxation oscillation, <br \/>\r\n enabling an effect of self-pulsed laser emission. In order to <br \/>\r\n investigate this effect, we propose a bullseye-shaped device with high <br \/>\r\n confinement of both the optical and the mechanical modes at the edge of <br \/>\r\n a disk combined with a dissipative structure in its vicinity. The <br \/>\r\n dispersive interaction is promoted by the strong photoelastic effect <br \/>\r\n while the dissipative mechanism is governed by the boundary motion <br \/>\r\n mechanism, enhanced by near-field interaction with the absorptive <br \/>\r\n structure. This hybrid optomechanical device is shown to lead sufficient <br \/>\r\n coupling for the experimental demonstration of the self-pulsed emission.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('207','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_207\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1109\/JPHOT.2018.2831001\" title=\"Follow DOI:10.1109\/JPHOT.2018.2831001\" target=\"_blank\">doi:10.1109\/JPHOT.2018.2831001<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('207','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_number\">18.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, Mario C M M;  Grieco, Andrew;  Frateschi, Newton C;  Fainman, Yeshaiahu<\/p><p class=\"tp_pub_title\"><a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/fourier-transform-spectrometer-on-silicon-with-thermo-optic-non-linearity-and-dispersion-correction-5\/\">Fourier transform spectrometer on silicon with thermo-optic  non-linearity and dispersion correction<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">NATURE COMMUNICATIONS, <\/span><span class=\"tp_pub_additional_volume\">vol. 9, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2041-1723<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_208\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('208','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_208\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('208','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_208\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('208','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_208\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Souza2018,<br \/>\r\ntitle = {Fourier transform spectrometer on silicon with thermo-optic  non-linearity and dispersion correction},<br \/>\r\nauthor = {Mario C M M Souza and Andrew Grieco and Newton C Frateschi and Yeshaiahu Fainman},<br \/>\r\nurl = {https:\/\/doi.org\/10.1038\/s41467-018-03004-6},<br \/>\r\ndoi = {10.1038\/s41467-018-03004-6},<br \/>\r\nissn = {2041-1723},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-02-01},<br \/>\r\njournal = {NATURE COMMUNICATIONS},<br \/>\r\nvolume = {9},<br \/>\r\npublisher = {NATURE PUBLISHING GROUP},<br \/>\r\naddress = {MACMILLAN BUILDING, 4 CRINAN ST, LONDON N1 9XW, ENGLAND},<br \/>\r\nabstract = {Miniaturized integrated spectrometers will have unprecedented impact on <br \/>\r\n applications ranging from unmanned aerial vehicles to mobile phones, and <br \/>\r\n silicon photonics promises to deliver compact, cost-effective devices. <br \/>\r\n Mirroring its ubiquitous free-space counterpart, a silicon <br \/>\r\n photonics-based Fourier transform spectrometer (Si-FTS) can bring <br \/>\r\n broadband operation and fine resolution to the chip scale. Here we <br \/>\r\n present the modeling and experimental demonstration of a thermally tuned <br \/>\r\n Si-FTS accounting for dispersion, thermo-optic non-linearity, and <br \/>\r\n thermal expansion. We show how these effects modify the relation between <br \/>\r\n the spectrum and interferogram of a light source and we develop a <br \/>\r\n quantitative correction procedure through calibration with a tunable <br \/>\r\n laser. We retrieve a broadband spectrum (7 THz around 193.4 THz with <br \/>\r\n 0.38-THz resolution consuming 2.5W per heater) and demonstrate the <br \/>\r\n Si-FTS resilience to fabrication variations - a major advantage for <br \/>\r\n large-scale manufacturing. Providing design flexibility and robustness, <br \/>\r\n the Si-FTS is poised to become a fundamental building block for on-chip <br \/>\r\n spectroscopy.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('208','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_208\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Miniaturized integrated spectrometers will have unprecedented impact on <br \/>\r\n applications ranging from unmanned aerial vehicles to mobile phones, and <br \/>\r\n silicon photonics promises to deliver compact, cost-effective devices. <br \/>\r\n Mirroring its ubiquitous free-space counterpart, a silicon <br \/>\r\n photonics-based Fourier transform spectrometer (Si-FTS) can bring <br \/>\r\n broadband operation and fine resolution to the chip scale. Here we <br \/>\r\n present the modeling and experimental demonstration of a thermally tuned <br \/>\r\n Si-FTS accounting for dispersion, thermo-optic non-linearity, and <br \/>\r\n thermal expansion. We show how these effects modify the relation between <br \/>\r\n the spectrum and interferogram of a light source and we develop a <br \/>\r\n quantitative correction procedure through calibration with a tunable <br \/>\r\n laser. We retrieve a broadband spectrum (7 THz around 193.4 THz with <br \/>\r\n 0.38-THz resolution consuming 2.5W per heater) and demonstrate the <br \/>\r\n Si-FTS resilience to fabrication variations - a major advantage for <br \/>\r\n large-scale manufacturing. Providing design flexibility and robustness, <br \/>\r\n the Si-FTS is poised to become a fundamental building block for on-chip <br \/>\r\n spectroscopy.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('208','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_208\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/doi.org\/10.1038\/s41467-018-03004-6\" title=\"https:\/\/doi.org\/10.1038\/s41467-018-03004-6\" target=\"_blank\">https:\/\/doi.org\/10.1038\/s41467-018-03004-6<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1038\/s41467-018-03004-6\" title=\"Follow DOI:10.1038\/s41467-018-03004-6\" target=\"_blank\">doi:10.1038\/s41467-018-03004-6<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('208','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">19.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Santos, La\u00eds F;  Inga, Marvyn;  Soares, Jorge H;  Alegre, Mayer T P;  Wiederhecker, G S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('236','tp_links')\" style=\"cursor:pointer;\">Dispersion Control in Silicon Oxide Wedge Microdisks<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JTu2A.111, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_236\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('236','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_236\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('236','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_236\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('236','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_236\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Santos:18,<br \/>\r\ntitle = {Dispersion Control in Silicon Oxide Wedge Microdisks},<br \/>\r\nauthor = {La\u00eds F Santos and Marvyn Inga and Jorge H Soares and Mayer T P Alegre and G S Wiederhecker},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111},<br \/>\r\ndoi = {10.1364\/CLEO_AT.2018.JTu2A.111},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JTu2A.111},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We demonstrate the generation of optical frequency combs by engineering the dispersion of a small radius (100 microns) thin wedge microcavity. The phase-matching of the excitation taper is also employed to inhibit avoided-crossings.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('236','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_236\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate the generation of optical frequency combs by engineering the dispersion of a small radius (100 microns) thin wedge microcavity. The phase-matching of the excitation taper is also employed to inhibit avoided-crossings.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('236','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_236\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_AT.2018.JTu2A.111\" title=\"Follow DOI:10.1364\/CLEO_AT.2018.JTu2A.111\" target=\"_blank\">doi:10.1364\/CLEO_AT.2018.JTu2A.111<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('236','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_number\">20.<\/div><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Wiederhecker, Gustavo S;  Alegre, Thiago Mayer P;  Dainese, Paulo;  Frateschi, Newton C<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('235','tp_links')\" style=\"cursor:pointer;\">Towards fabless optomechanics: enhancing light and sound interaction in a CMOS-complatible platform<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Latin America Optics and Photonics Conference, <\/span><span class=\"tp_pub_additional_pages\">pp. W3E.2, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_235\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('235','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_235\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('235','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_235\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('235','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_235\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Wiederhecker:18,<br \/>\r\ntitle = {Towards fabless optomechanics: enhancing light and sound interaction in a CMOS-complatible platform},<br \/>\r\nauthor = {Gustavo S Wiederhecker and Thiago Mayer P Alegre and Paulo Dainese and Newton C Frateschi},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2},<br \/>\r\ndoi = {10.1364\/LAOP.2018.W3E.2},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-01-01},<br \/>\r\nbooktitle = {Latin America Optics and Photonics Conference},<br \/>\r\njournal = {Latin America Optics and Photonics Conference},<br \/>\r\npages = {W3E.2},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {In this talk we will review our recent efforts in enabling strong interaction between light and mechanical modes using a mixed foundry and in-house fabrication approach.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('235','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_235\" style=\"display:none;\"><div class=\"tp_abstract_entry\">In this talk we will review our recent efforts in enabling strong interaction between light and mechanical modes using a mixed foundry and in-house fabrication approach.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('235','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_235\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/LAOP.2018.W3E.2\" title=\"Follow DOI:10.1364\/LAOP.2018.W3E.2\" target=\"_blank\">doi:10.1364\/LAOP.2018.W3E.2<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('235','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><\/div><div class=\"tablenav\"><div class=\"tablenav-pages\"><span class=\"displaying-num\">105 entries<\/span> <a class=\"page-numbers button disabled\">&laquo;<\/a> <a class=\"page-numbers button disabled\">&lsaquo;<\/a> 1 of 6 <a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/recent-publications\/?limit=2&amp;tgid=&amp;yr=&amp;type=&amp;usr=&amp;auth=&amp;tsr=\" title=\"next page\" class=\"page-numbers button\">&rsaquo;<\/a> <a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/recent-publications\/?limit=6&amp;tgid=&amp;yr=&amp;type=&amp;usr=&amp;auth=&amp;tsr=\" title=\"last page\" class=\"page-numbers button\">&raquo;<\/a> <\/div><\/div><\/div><\/p>\n<div class=\"teachpress_pub_list\"><form name=\"tppublistform\" method=\"get\"><a name=\"tppubs\" id=\"tppubs\"><\/a><\/form><div class=\"teachpress_publication_list\"><h3 class=\"tp_h3\" id=\"tp_h3_2020\">2020<\/h3><h3 class=\"tp_h3\" id=\"tp_h3_article\">Journal Articles<\/h3><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Carvalho, Nat\u00e1lia C;  Kersul, Cau\u00ea M;  Frateschi, Newton C;  Wiederhecker, Gustavo S;  Alegre, Thiago Mayer P<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('240','tp_links')\" style=\"cursor:pointer;\">Quasinormal-Mode Perturbation Theory for Dissipative and Dispersive Optomechanics<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Physical Review Letters, <\/span><span class=\"tp_pub_additional_volume\">vol. 125, <\/span><span class=\"tp_pub_additional_number\">no. 23, <\/span><span class=\"tp_pub_additional_pages\">pp. 233601, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 0031-9007<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_240\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('240','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_240\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('240','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_240\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('240','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_240\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{primo2020dissipative,<br \/>\r\ntitle = {Quasinormal-Mode Perturbation Theory for Dissipative and Dispersive Optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Nat\u00e1lia C Carvalho and Cau{\u00ea} M Kersul and Newton C Frateschi and Gustavo S Wiederhecker and Thiago Mayer P Alegre},<br \/>\r\nurl = {http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125.233601},<br \/>\r\ndoi = {10.1103\/PhysRevLett.125.233601},<br \/>\r\nissn = {0031-9007},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-12-01},<br \/>\r\njournal = {Physical Review Letters},<br \/>\r\nvolume = {125},<br \/>\r\nnumber = {23},<br \/>\r\npages = {233601},<br \/>\r\nabstract = {Despite the several novel features arising from the dissipative optomechanical coupling, such effect remains vastly unexplored due to the lack of a simple formalism that captures non-Hermiticity in optomechanical systems. In this Letter, we show that quasinormal-mode-based perturbation theory is capable of correctly predicting both dispersive and dissipative optomechanical couplings. We validate our model through simulations and also by comparison with experimental results reported in the literature. Finally, we apply this formalism to plasmonic systems, used for molecular optomechanics, where strong dissipative coupling signatures in the amplification of vibrational modes are observed.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('240','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_240\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Despite the several novel features arising from the dissipative optomechanical coupling, such effect remains vastly unexplored due to the lack of a simple formalism that captures non-Hermiticity in optomechanical systems. In this Letter, we show that quasinormal-mode-based perturbation theory is capable of correctly predicting both dispersive and dissipative optomechanical couplings. We validate our model through simulations and also by comparison with experimental results reported in the literature. Finally, we apply this formalism to plasmonic systems, used for molecular optomechanics, where strong dissipative coupling signatures in the amplification of vibrational modes are observed.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('240','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_240\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-arxiv\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125.233601\" title=\"http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125[...]\" target=\"_blank\">http:\/\/arxiv.org\/abs\/2006.00692 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevLett.125[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1103\/PhysRevLett.125.233601\" title=\"Follow DOI:10.1103\/PhysRevLett.125.233601\" target=\"_blank\">doi:10.1103\/PhysRevLett.125.233601<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('240','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Inga, Marvyn;  Fujii, La\u00eds; da Silva Filho, Jos\u00e9 Maria C;  Palhares, Jo\u00e3o Henrique Quintino;  Ferlauto, Andre Santarosa;  Marques, Francisco C;  Alegre, Thiago P Mayer;  Wiederhecker, Gustavo<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('241','tp_links')\" style=\"cursor:pointer;\">Alumina coating for dispersion management in ultra-high Q microresonators<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">APL Photonics, <\/span><span class=\"tp_pub_additional_volume\">vol. 5, <\/span><span class=\"tp_pub_additional_number\">no. 11, <\/span><span class=\"tp_pub_additional_pages\">pp. 116107, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2378-0967<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_resource_link\"><a id=\"tp_links_sh_241\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('241','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_241\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('241','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_241\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Inga2020,<br \/>\r\ntitle = {Alumina coating for dispersion management in ultra-high Q microresonators},<br \/>\r\nauthor = {Marvyn Inga and La\u00eds Fujii and Jos\u00e9 Maria C {da Silva Filho} and Jo{\u00e3}o Henrique {Quintino Palhares} and Andre Santarosa Ferlauto and Francisco C Marques and Thiago P {Mayer Alegre} and Gustavo Wiederhecker},<br \/>\r\nurl = {http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839},<br \/>\r\ndoi = {10.1063\/5.0028839},<br \/>\r\nissn = {2378-0967},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-11-01},<br \/>\r\njournal = {APL Photonics},<br \/>\r\nvolume = {5},<br \/>\r\nnumber = {11},<br \/>\r\npages = {116107},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('241','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_241\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839\" title=\"http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839\" target=\"_blank\">http:\/\/aip.scitation.org\/doi\/10.1063\/5.0028839<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1063\/5.0028839\" title=\"Follow DOI:10.1063\/5.0028839\" target=\"_blank\">doi:10.1063\/5.0028839<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('241','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Li, Jie;  Wallucks, Andreas;  Benevides, Rodrigo;  Fiaschi, Niccolo;  Hensen, Bas;  Alegre, Thiago Mayer P;  Gr\u00f6blacher, Simon<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('242','tp_links')\" style=\"cursor:pointer;\">Proposal for optomechanical quantum teleportation<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Physical Review A, <\/span><span class=\"tp_pub_additional_volume\">vol. 102, <\/span><span class=\"tp_pub_additional_number\">no. 3, <\/span><span class=\"tp_pub_additional_pages\">pp. 032402, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2469-9926<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_242\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('242','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_242\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('242','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_242\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('242','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_242\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{li2020proposal,<br \/>\r\ntitle = {Proposal for optomechanical quantum teleportation},<br \/>\r\nauthor = {Jie Li and Andreas Wallucks and Rodrigo Benevides and Niccolo Fiaschi and Bas Hensen and Thiago Mayer P Alegre and Simon Gr\u00f6blacher},<br \/>\r\nurl = {http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevA.102.032402},<br \/>\r\ndoi = {10.1103\/PhysRevA.102.032402},<br \/>\r\nissn = {2469-9926},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-09-01},<br \/>\r\njournal = {Physical Review A},<br \/>\r\nvolume = {102},<br \/>\r\nnumber = {3},<br \/>\r\npages = {032402},<br \/>\r\nabstract = {We present a novel discrete-variable quantum teleportation scheme using pulsed optomechanics. In our proposal, we demonstrate how an unknown optical input state can be transferred onto the joint state of a pair of mechanical oscillators, without physically interacting with one another. We further analyze how experimental imperfections will affect the fidelity of the teleportation and highlight how our scheme can be realized in current state-of-the-art optomechanical systems.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('242','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_242\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We present a novel discrete-variable quantum teleportation scheme using pulsed optomechanics. In our proposal, we demonstrate how an unknown optical input state can be transferred onto the joint state of a pair of mechanical oscillators, without physically interacting with one another. We further analyze how experimental imperfections will affect the fidelity of the teleportation and highlight how our scheme can be realized in current state-of-the-art optomechanical systems.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('242','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_242\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-arxiv\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 https:\/\/link.aps.org\/doi\/10.1103\/PhysRevA.102.032402\" title=\"http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 ht[...]\" target=\"_blank\">http:\/\/arxiv.org\/abs\/2005.08860 http:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402 ht[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1103\/PhysRevA.102.032402\" title=\"Follow DOI:10.1103\/PhysRevA.102.032402\" target=\"_blank\">doi:10.1103\/PhysRevA.102.032402<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('242','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Fujii, L;  Inga, M;  Soares, J H;  Espinel, Y A V;  Alegre, T P Mayer;  Wiederhecker, G S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('231','tp_links')\" style=\"cursor:pointer;\">Dispersion tailoring in wedge microcavities for Kerr comb generation<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Optics Letters, <\/span><span class=\"tp_pub_additional_volume\">vol. 45, <\/span><span class=\"tp_pub_additional_number\">no. 12, <\/span><span class=\"tp_pub_additional_pages\">pp. 3232, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 0146-9592<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_231\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('231','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_231\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('231','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_231\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('231','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_231\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Fujii2020,<br \/>\r\ntitle = {Dispersion tailoring in wedge microcavities for Kerr comb generation},<br \/>\r\nauthor = {L Fujii and M Inga and J H Soares and Y A V Espinel and T P {Mayer Alegre} and G S Wiederhecker},<br \/>\r\nurl = {https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232},<br \/>\r\ndoi = {10.1364\/ol.393294},<br \/>\r\nissn = {0146-9592},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-06-01},<br \/>\r\njournal = {Optics Letters},<br \/>\r\nvolume = {45},<br \/>\r\nnumber = {12},<br \/>\r\npages = {3232},<br \/>\r\nabstract = {The shaping of group velocity dispersion in microresonators is an important component in the generation of wideband optical frequency combs. Small resonators - with tight bending radii - offer the large free-spectral range desirable for wide comb formation. However, the tighter bending usually limit comb formation as it enhances normal group velocity dispersion. We experimentally demonstrate that engineering the sidewall angle of small-radius (100 $mu$m), 3 $mu$m-thick silica wedge microdisks enables dispersion tuning in both normal and anomalous regimes, without significantly affecting the free spectral range. A microdisk with wedge angle of $55^circ$ (anomalous dispersion) is used to demonstrate a 300 nm bandwidth Kerr optical frequency comb.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('231','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_231\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The shaping of group velocity dispersion in microresonators is an important component in the generation of wideband optical frequency combs. Small resonators - with tight bending radii - offer the large free-spectral range desirable for wide comb formation. However, the tighter bending usually limit comb formation as it enhances normal group velocity dispersion. We experimentally demonstrate that engineering the sidewall angle of small-radius (100 $mu$m), 3 $mu$m-thick silica wedge microdisks enables dispersion tuning in both normal and anomalous regimes, without significantly affecting the free spectral range. A microdisk with wedge angle of $55^circ$ (anomalous dispersion) is used to demonstrate a 300 nm bandwidth Kerr optical frequency comb.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('231','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_231\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232\" title=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232\" target=\"_blank\">https:\/\/www.osapublishing.org\/abstract.cfm?URI=ol-45-12-3232<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/ol.393294\" title=\"Follow DOI:10.1364\/ol.393294\" target=\"_blank\">doi:10.1364\/ol.393294<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('231','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Melo, Emerson G;  Ribeiro, Ana L A;  Benevides, Rodrigo S;  Zuben, Antonio A G V; dos Santos, Marcos V Puydinger;  Silva, Alexandre A;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('232','tp_links')\" style=\"cursor:pointer;\">Bright and Vivid Diffractive\u2013Plasmonic Reflective Filters for Color Generation<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">ACS Applied Nano Materials, <\/span><span class=\"tp_pub_additional_volume\">vol. 3, <\/span><span class=\"tp_pub_additional_number\">no. 2, <\/span><span class=\"tp_pub_additional_pages\">pp. 1111\u20131117, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2574-0970<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_232\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('232','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_232\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('232','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_232\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('232','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_232\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Melo2020,<br \/>\r\ntitle = {Bright and Vivid Diffractive\u2013Plasmonic Reflective Filters for Color Generation},<br \/>\r\nauthor = {Emerson G Melo and Ana L A Ribeiro and Rodrigo S Benevides and Antonio A G V Zuben and Marcos V {Puydinger dos Santos} and Alexandre A Silva and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508},<br \/>\r\ndoi = {10.1021\/acsanm.9b02508},<br \/>\r\nissn = {2574-0970},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-02-01},<br \/>\r\njournal = {ACS Applied Nano Materials},<br \/>\r\nvolume = {3},<br \/>\r\nnumber = {2},<br \/>\r\npages = {1111--1117},<br \/>\r\nabstract = {The desire to reproduce vivid colors such as those found in birds, fishes, flowers, and insects has driven extensive research into nanostructured surfaces especially because of their high spatial resolution. Using a periodic silicon-patterned structure coated with aluminum, we combine two distinct and yet interconnected effects to produce bright and vivid color surfaces. A genetic algorithm optimization process was used to fine-tune both the diffraction and plasmonic effects to obtain reflective color filters for the red, green, and blue colors. The obtained structures are suitable for displays, image applications, color sensors, and optical filters.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('232','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_232\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The desire to reproduce vivid colors such as those found in birds, fishes, flowers, and insects has driven extensive research into nanostructured surfaces especially because of their high spatial resolution. Using a periodic silicon-patterned structure coated with aluminum, we combine two distinct and yet interconnected effects to produce bright and vivid color surfaces. A genetic algorithm optimization process was used to fine-tune both the diffraction and plasmonic effects to obtain reflective color filters for the red, green, and blue colors. The obtained structures are suitable for displays, image applications, color sensors, and optical filters.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('232','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_232\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508\" title=\"https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508\" target=\"_blank\">https:\/\/pubs.acs.org\/doi\/10.1021\/acsanm.9b02508<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1021\/acsanm.9b02508\" title=\"Follow DOI:10.1021\/acsanm.9b02508\" target=\"_blank\">doi:10.1021\/acsanm.9b02508<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('232','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Benevides, Rodrigo;  M\u00e9nard, Micha\u00ebl;  Wiederhecker, Gustavo S;  Alegre, Thiago P Mayer<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('230','tp_links')\" style=\"cursor:pointer;\"> Ar\/Cl 2 etching of GaAs optomechanical microdisks fabricated with positive electroresist <\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Optical Materials Express, <\/span><span class=\"tp_pub_additional_volume\">vol. 10, <\/span><span class=\"tp_pub_additional_number\">no. 1, <\/span><span class=\"tp_pub_additional_pages\">pp. 57, <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2159-3930<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_230\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('230','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_230\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('230','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_230\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('230','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_230\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Benevides2020,<br \/>\r\ntitle = { Ar\/Cl 2 etching of GaAs optomechanical microdisks fabricated with positive electroresist },<br \/>\r\nauthor = {Rodrigo Benevides and Micha{\u00eb}l M\u00e9nard and Gustavo S Wiederhecker and Thiago P {Mayer Alegre}},<br \/>\r\nurl = {https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57},<br \/>\r\ndoi = {10.1364\/OME.10.000057},<br \/>\r\nissn = {2159-3930},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\njournal = {Optical Materials Express},<br \/>\r\nvolume = {10},<br \/>\r\nnumber = {1},<br \/>\r\npages = {57},<br \/>\r\nabstract = {A method to fabricate GaAs microcavities using only a soft mask with an electrolithographic pattern in an inductively coupled plasma etching is presented. A careful characterization of the fabrication process pinpointing the main routes for a smooth device sidewall is discussed. Using the final recipe, optomechanical microdisk resonators are fabricated. The results show a very high optical quality factors of $Q_textopt&gt;2times 10^5$, among the largest already reported for dry-etching devices. The final devices are also shown to present high mechanical quality factors and an optomechanical vacuum coupling constant of $g_0=2pitimes 13.6$ kHz enabling self-sustainable mechanical oscillations for an optical input power above $1$ mW.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('230','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_230\" style=\"display:none;\"><div class=\"tp_abstract_entry\">A method to fabricate GaAs microcavities using only a soft mask with an electrolithographic pattern in an inductively coupled plasma etching is presented. A careful characterization of the fabrication process pinpointing the main routes for a smooth device sidewall is discussed. Using the final recipe, optomechanical microdisk resonators are fabricated. The results show a very high optical quality factors of $Q_textopt&gt;2times 10^5$, among the largest already reported for dry-etching devices. The final devices are also shown to present high mechanical quality factors and an optomechanical vacuum coupling constant of $g_0=2pitimes 13.6$ kHz enabling self-sustainable mechanical oscillations for an optical input power above $1$ mW.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('230','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_230\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57\" title=\"https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57\" target=\"_blank\">https:\/\/www.osapublishing.org\/abstract.cfm?URI=ome-10-1-57<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OME.10.000057\" title=\"Follow DOI:10.1364\/OME.10.000057\" target=\"_blank\">doi:10.1364\/OME.10.000057<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('230','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_inproceedings\">Proceedings Articles<\/h3><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Carvalho, Natalia C;  Benevides, Rodrigo;  M\u00e9nard, Micha\u00ebl;  Wiederhecker, Gustavo S;  Frateschi, Newton C;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('243','tp_links')\" style=\"cursor:pointer;\">High-frequency GaAs bullseye optomechanical resonator<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STh1R.5, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_243\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('243','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_243\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('243','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_243\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('243','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_243\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Carvalho2020,<br \/>\r\ntitle = {High-frequency GaAs bullseye optomechanical resonator},<br \/>\r\nauthor = {Natalia C Carvalho and Rodrigo Benevides and Micha{\u00eb}l M\u00e9nard and Gustavo S Wiederhecker and Newton C Frateschi and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2020.STh1R.5},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STh1R.5},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We fabricated and measured a GaAs bullseye resonator able to operate above 3 GHz when coupled to whispering gallery optical modes. Our large phononic bandgap allowed us to observe the symmetry break caused by the material anisotropy and obtain optomechanical coupling rates above 30 kHz.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('243','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_243\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We fabricated and measured a GaAs bullseye resonator able to operate above 3 GHz when coupled to whispering gallery optical modes. Our large phononic bandgap allowed us to observe the symmetry break caused by the material anisotropy and obtain optomechanical coupling rates above 30 kHz.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('243','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_243\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.o[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.5 https:\/\/www.o[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2020.STh1R.5\" title=\"Follow DOI:10.1364\/CLEO_SI.2020.STh1R.5\" target=\"_blank\">doi:10.1364\/CLEO_SI.2020.STh1R.5<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('243','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Rodrigues, Caique C;  Kersul, Caue M;  Lipson, Michal;  Alegre, Thiago P M;  Wiederhecker, Gustavo S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('244','tp_links')\" style=\"cursor:pointer;\">High-Harmonic Synchronization of Optomechanical Oscillators<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JW2B.27, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_244\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('244','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_244\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('244','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_244\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('244','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_244\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Rodrigues2020,<br \/>\r\ntitle = {High-Harmonic Synchronization of Optomechanical Oscillators},<br \/>\r\nauthor = {Caique C Rodrigues and Caue M Kersul and Michal Lipson and Thiago P M Alegre and Gustavo S Wiederhecker},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27},<br \/>\r\ndoi = {10.1364\/CLEO_AT.2020.JW2B.27},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JW2B.27},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We experimentally demonstrate injection locking of an optomechanical oscillator driven at multiple harmonics of its fundamental frequency. The measured Arnold tongues show strongest synchronization when driven at even harmonics.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('244','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_244\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We experimentally demonstrate injection locking of an optomechanical oscillator driven at multiple harmonics of its fundamental frequency. The measured Arnold tongues show strongest synchronization when driven at even harmonics.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('244','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_244\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.o[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JW2B.27 https:\/\/www.o[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_AT.2020.JW2B.27\" title=\"Follow DOI:10.1364\/CLEO_AT.2020.JW2B.27\" target=\"_blank\">doi:10.1364\/CLEO_AT.2020.JW2B.27<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('244','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Carvalho, Natalia C;  Kersul, Cau\u00ea M;  Wiederhecker, Gustavo S;  Frateschi, Newton C;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('245','tp_links')\" style=\"cursor:pointer;\">Non-Hermitian Optomechanics<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. FTh3C.3, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_245\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('245','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_245\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('245','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_245\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('245','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_245\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Primo2020b,<br \/>\r\ntitle = {Non-Hermitian Optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Natalia C Carvalho and Cau{\u00ea} M Kersul and Gustavo S Wiederhecker and Newton C Frateschi and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3},<br \/>\r\ndoi = {10.1364\/CLEO_QELS.2020.FTh3C.3},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {FTh3C.3},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We propose and numerically validate a modified perturbation theory that captures non-Hermitian features present in dissipative optomechanical systems. Our theory predicts different behaviors than commonly used perturbation theories derived assuming purely Hermitian dynamics.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('245','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_245\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We propose and numerically validate a modified perturbation theory that captures non-Hermitian features present in dissipative optomechanical systems. Our theory predicts different behaviors than commonly used perturbation theories derived assuming purely Hermitian dynamics.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('245','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_245\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.3 https:\/\/www[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_QELS.2020.FTh3C.3\" title=\"Follow DOI:10.1364\/CLEO_QELS.2020.FTh3C.3\" target=\"_blank\">doi:10.1364\/CLEO_QELS.2020.FTh3C.3<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('245','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\">de Oliveira Zurita, Roberto;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('246','tp_links')\" style=\"cursor:pointer;\">Strong confinement of short-wave Brillouin phonons in silicon waveguide periodic lattices<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. FTh3C.2, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_246\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('246','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_246\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('246','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_246\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('246','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_246\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{DeOliveiraZurita2020,<br \/>\r\ntitle = {Strong confinement of short-wave Brillouin phonons in silicon waveguide periodic lattices},<br \/>\r\nauthor = {Roberto {de Oliveira Zurita} and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2},<br \/>\r\ndoi = {10.1364\/CLEO_QELS.2020.FTh3C.2},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {FTh3C.2},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We propose a feasible silicon waveguide design that can strongly trap short-wavelength Brillouin phonons. Intramodal backward Brillouin gain is improved about 4.3 while radiation losses are suppressed. The structure could be implemented using SOI technology.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('246','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_246\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We propose a feasible silicon waveguide design that can strongly trap short-wavelength Brillouin phonons. Intramodal backward Brillouin gain is improved about 4.3 while radiation losses are suppressed. The structure could be implemented using SOI technology.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('246','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_246\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-FTh3C.2 https:\/\/www[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_QELS.2020.FTh3C.2\" title=\"Follow DOI:10.1364\/CLEO_QELS.2020.FTh3C.2\" target=\"_blank\">doi:10.1364\/CLEO_QELS.2020.FTh3C.2<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('246','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Inga, Marvyn; dos Santos, Lais Fujii; da Silva Filho, Jose M C;  Espinel, Y A V;  Marques, Francisco C;  Alegre, Thiago P M;  Wiederhecker, Gustavo S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('247','tp_links')\" style=\"cursor:pointer;\">Tailoring group-velocity dispersion in microspheres with alumina coating<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JTh2C.4, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_247\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('247','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_247\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('247','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_247\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('247','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_247\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Inga2020b,<br \/>\r\ntitle = {Tailoring group-velocity dispersion in microspheres with alumina coating},<br \/>\r\nauthor = {Marvyn Inga and Lais Fujii dos Santos and Jose M C {da Silva Filho} and Y A V Espinel and Francisco C Marques and Thiago P M Alegre and Gustavo S Wiederhecker},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JTh2C.4},<br \/>\r\ndoi = {10.1364\/CLEO_AT.2020.JTh2C.4},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JTh2C.4},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We experimentally demonstrate that the group-velocity dispersion of silica microspheres can be engineered by coating it with nanometer-thick layers of alumina (Al2O3). The ultra-high optical quality factor (&gt; 107) achieved allows for the generation of optical frequency combs.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('247','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_247\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We experimentally demonstrate that the group-velocity dispersion of silica microspheres can be engineered by coating it with nanometer-thick layers of alumina (Al2O3). The ultra-high optical quality factor (&gt; 107) achieved allows for the generation of optical frequency combs.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('247','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_247\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_AT-2020-JTh2C.4\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2020-JTh2C.4 https:\/\/www[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_AT.2020.JTh2C.4\" title=\"Follow DOI:10.1364\/CLEO_AT.2020.JTh2C.4\" target=\"_blank\">doi:10.1364\/CLEO_AT.2020.JTh2C.4<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('247','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Benevides, Rodrigo;  Kersul, Cau\u00ea M; de Assis, Pierre-Louis;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('248','tp_links')\" style=\"cursor:pointer;\">Thermodynamic model for photothermal effects in optomechanics<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STh1R.6, <\/span><span class=\"tp_pub_additional_publisher\">OSA, <\/span><span class=\"tp_pub_additional_address\">Washington, D.C., <\/span><span class=\"tp_pub_additional_year\">2020<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-943580-76-7<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_248\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('248','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_248\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('248','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_248\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('248','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_248\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Primo2020a,<br \/>\r\ntitle = {Thermodynamic model for photothermal effects in optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Rodrigo Benevides and Cau{\u00ea} M Kersul and Pierre-Louis de Assis and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2020.STh1R.6},<br \/>\r\nisbn = {978-1-943580-76-7},<br \/>\r\nyear  = {2020},<br \/>\r\ndate = {2020-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STh1R.6},<br \/>\r\npublisher = {OSA},<br \/>\r\naddress = {Washington, D.C.},<br \/>\r\nseries = {OSA Technical Digest},<br \/>\r\nabstract = {We derive and validate a model for the photothermal forces that act on optomechanical cavities. Our results not only enable the prediction of such effect but also show that it is much stronger than previously estimated.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('248','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_248\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We derive and validate a model for the photothermal forces that act on optomechanical cavities. Our results not only enable the prediction of such effect but also show that it is much stronger than previously estimated.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('248','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_248\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.o[...]\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2020-STh1R.6 https:\/\/www.o[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2020.STh1R.6\" title=\"Follow DOI:10.1364\/CLEO_SI.2020.STh1R.6\" target=\"_blank\">doi:10.1364\/CLEO_SI.2020.STh1R.6<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('248','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_2019\">2019<\/h3><h3 class=\"tp_h3\" id=\"tp_h3_article\">Journal Articles<\/h3><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Barnard, Arthur W;  Zhang, Mian;  Wiederhecker, Gustavo S;  Lipson, Michal;  McEuen, Paul L<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('224','tp_links')\" style=\"cursor:pointer;\">Real-time vibrations of a carbon nanotube<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Nature, <\/span><span class=\"tp_pub_additional_volume\">vol. 566, <\/span><span class=\"tp_pub_additional_number\">no. 7742, <\/span><span class=\"tp_pub_additional_pages\">pp. 89\u201393, <\/span><span class=\"tp_pub_additional_year\">2019<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 1476-4687<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_224\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('224','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_224\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('224','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_224\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('224','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_224\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Barnard:2019aa,<br \/>\r\ntitle = {Real-time vibrations of a carbon nanotube},<br \/>\r\nauthor = {Arthur W Barnard and Mian Zhang and Gustavo S Wiederhecker and Michal Lipson and Paul L McEuen},<br \/>\r\nurl = {https:\/\/doi.org\/10.1038\/s41586-018-0861-0},<br \/>\r\ndoi = {10.1038\/s41586-018-0861-0},<br \/>\r\nisbn = {1476-4687},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\njournal = {Nature},<br \/>\r\nvolume = {566},<br \/>\r\nnumber = {7742},<br \/>\r\npages = {89--93},<br \/>\r\nabstract = {The field of miniature mechanical oscillators is rapidly evolving, with emerging applications including signal processing, biological detection1 and fundamental tests of quantum mechanics2. As the dimensions of a mechanical oscillator shrink to the molecular scale, such as in a carbon nanotube resonator3--7, their vibrations become increasingly coupled and strongly interacting8,9 until even weak thermal fluctuations could make the oscillator nonlinear10--13. The mechanics at this scale possesses rich dynamics, unexplored because an efficient way of detecting the motion in real time is lacking. Here we directly measure the thermal vibrations of a carbon nanotube in real time using a high-finesse micrometre-scale silicon nitride optical cavity as a sensitive photonic microscope. With the high displacement sensitivity of 700 fm Hz\u22121\/2 and the fine time resolution of this technique, we were able to discover a realm of dynamics undetected by previous time-averaged measurements and a room-temperature coherence that is nearly three orders of magnitude longer than previously reported. We find that the discrepancy in the coherence stems from long-time non-equilibrium dynamics, analogous to the Fermi--Pasta--Ulam--Tsingou recurrence seen in nonlinear systems14. Our data unveil the emergence of a weakly chaotic mechanical breather15, in which vibrational energy is recurrently shared among several resonance modes---dynamics that we are able to reproduce using a simple numerical model. These experiments open up the study of nonlinear mechanical systems in the Brownian limit (that is, when a system is driven solely by thermal fluctuations) and present an integrated, sensitive, high-bandwidth nanophotonic interface for carbon nanotube resonators.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('224','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_224\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The field of miniature mechanical oscillators is rapidly evolving, with emerging applications including signal processing, biological detection1 and fundamental tests of quantum mechanics2. As the dimensions of a mechanical oscillator shrink to the molecular scale, such as in a carbon nanotube resonator3--7, their vibrations become increasingly coupled and strongly interacting8,9 until even weak thermal fluctuations could make the oscillator nonlinear10--13. The mechanics at this scale possesses rich dynamics, unexplored because an efficient way of detecting the motion in real time is lacking. Here we directly measure the thermal vibrations of a carbon nanotube in real time using a high-finesse micrometre-scale silicon nitride optical cavity as a sensitive photonic microscope. With the high displacement sensitivity of 700 fm Hz\u22121\/2 and the fine time resolution of this technique, we were able to discover a realm of dynamics undetected by previous time-averaged measurements and a room-temperature coherence that is nearly three orders of magnitude longer than previously reported. We find that the discrepancy in the coherence stems from long-time non-equilibrium dynamics, analogous to the Fermi--Pasta--Ulam--Tsingou recurrence seen in nonlinear systems14. Our data unveil the emergence of a weakly chaotic mechanical breather15, in which vibrational energy is recurrently shared among several resonance modes---dynamics that we are able to reproduce using a simple numerical model. These experiments open up the study of nonlinear mechanical systems in the Brownian limit (that is, when a system is driven solely by thermal fluctuations) and present an integrated, sensitive, high-bandwidth nanophotonic interface for carbon nanotube resonators.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('224','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_224\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/doi.org\/10.1038\/s41586-018-0861-0\" title=\"https:\/\/doi.org\/10.1038\/s41586-018-0861-0\" target=\"_blank\">https:\/\/doi.org\/10.1038\/s41586-018-0861-0<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1038\/s41586-018-0861-0\" title=\"Follow DOI:10.1038\/s41586-018-0861-0\" target=\"_blank\">doi:10.1038\/s41586-018-0861-0<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('224','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Wiederhecker, Gustavo S;  Dainese, Paulo;  Alegre, Thiago Mayer P<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('225','tp_links')\" style=\"cursor:pointer;\">Brillouin optomechanics in nanophotonic structures<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">APL Photonic, <\/span><span class=\"tp_pub_additional_volume\">vol. 4, <\/span><span class=\"tp_pub_additional_number\">no. 7, <\/span><span class=\"tp_pub_additional_pages\">pp. 071101, <\/span><span class=\"tp_pub_additional_year\">2019<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_225\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('225','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_225\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('225','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_225\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('225','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_225\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Wiederhecker:2019ey,<br \/>\r\ntitle = {Brillouin optomechanics in nanophotonic structures},<br \/>\r\nauthor = {Gustavo S Wiederhecker and Paulo Dainese and Thiago Mayer P Alegre},<br \/>\r\nurl = {http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169},<br \/>\r\ndoi = {10.1063\/1.5088169},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\njournal = {APL Photonic},<br \/>\r\nvolume = {4},<br \/>\r\nnumber = {7},<br \/>\r\npages = {071101},<br \/>\r\npublisher = {AIP Publishing LLC},<br \/>\r\nabstract = {The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary effects\u2014interplay to foster exciting possibilities in this field. In order to stimulate beginners into this growing research field, this tutorial is accompanied by all the discussed simulation material based on a widespread commercial finite-element solver.The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary ef...},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('225','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_225\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary effects\u2014interplay to foster exciting possibilities in this field. In order to stimulate beginners into this growing research field, this tutorial is accompanied by all the discussed simulation material based on a widespread commercial finite-element solver.The interaction between light and mesoscopic mechanical degrees of freedom has been investigated under various perspectives, from spectroscopy in condensed matter, optical tweezer particle trapping, and long-haul optical fiber communication system penalties to gravitational-wave detector noise. In the context of integrated photonics, two topics with dissimilar origins\u2014cavity optomechanics and guided wave Brillouin scattering\u2014are rooted in the manipulation and control of the energy exchange between trapped light and mechanical modes. In this tutorial, we explore the impact of optical and mechanical subwavelength confinement on the interaction among these waves, coined as Brillouin optomechanics. At this spatial scale, optical and mechanical fields are fully vectorial and the common intuition that more intense fields lead to stronger interaction may fail. Here, we provide a thorough discussion on how the two major physical effects responsible for the Brillouin interaction\u2014photoelastic and moving-boundary ef...<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('225','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_225\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169\" title=\"http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169\" target=\"_blank\">http:\/\/aip.scitation.org\/doi\/10.1063\/1.5088169<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1063\/1.5088169\" title=\"Follow DOI:10.1063\/1.5088169\" target=\"_blank\">doi:10.1063\/1.5088169<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('225','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_inproceedings\">Proceedings Articles<\/h3><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Primo, Andr\u00e9 G;  Benevides, Rodrigo;  Kersul, Cau\u00ea M; de Assis, Pierre-Louis;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('233','tp_links')\" style=\"cursor:pointer;\">Modelling bolometric backaction in cavity optomechanics<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Frontiers in Optics $+$ Laser Science APS\/DLS, <\/span><span class=\"tp_pub_additional_pages\">pp. JTu3A.87, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2019<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_233\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('233','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_233\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('233','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_233\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('233','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_233\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Primo:19,<br \/>\r\ntitle = {Modelling bolometric backaction in cavity optomechanics},<br \/>\r\nauthor = {Andr\u00e9 G Primo and Rodrigo Benevides and Cau\u00ea M Kersul and Pierre-Louis de Assis and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87},<br \/>\r\ndoi = {10.1364\/FIO.2019.JTu3A.87},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\nbooktitle = {Frontiers in Optics $+$ Laser Science APS\/DLS},<br \/>\r\njournal = {Frontiers in Optics $+$ Laser Science APS\/DLS},<br \/>\r\npages = {JTu3A.87},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {From thermodynamic considerations we derive a model for thermally driven stresses that induce changes on acoustic dynamics, enabling the engineering of devices where these effects are suppressed or enhanced when compared to optomechanical backaction.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('233','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_233\" style=\"display:none;\"><div class=\"tp_abstract_entry\">From thermodynamic considerations we derive a model for thermally driven stresses that induce changes on acoustic dynamics, enabling the engineering of devices where these effects are suppressed or enhanced when compared to optomechanical backaction.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('233','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_233\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2019-JTu3A.87<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/FIO.2019.JTu3A.87\" title=\"Follow DOI:10.1364\/FIO.2019.JTu3A.87\" target=\"_blank\">doi:10.1364\/FIO.2019.JTu3A.87<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('233','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_techreport\">Technical Reports<\/h3><div class=\"tp_publication tp_publication_techreport\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Wiederhecker, Gustavo;  Dainese, Paulo;  Alegre, Thiago P Mayer<\/p><p class=\"tp_pub_title\"><a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/data-and-simulations-files-for-the-tutorial-article\/\">Data and simulations files for the tutorial article <\/a> <span class=\"tp_pub_type tp_  techreport\">Technical Report<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_year\">2019<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_226\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('226','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_226\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('226','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_226\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('226','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_226\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@techreport{Wiederhecker:2019bq,<br \/>\r\ntitle = {Data and simulations files for the tutorial article },<br \/>\r\nauthor = {Gustavo Wiederhecker and Paulo Dainese and Thiago P Mayer Alegre},<br \/>\r\nurl = {https:\/\/zenodo.org\/record\/1971811},<br \/>\r\ndoi = {10.5281\/zenodo.1971811},<br \/>\r\nyear  = {2019},<br \/>\r\ndate = {2019-01-01},<br \/>\r\nabstract = {Data and simulations files for the tutorial article \"Brillouin optomechanics in nanophotonic structures\". Published in APL Photonics Special issue \u00d6ptoacoustics\u2014Advances in high-frequency optomechanics and Brillouin scattering\" - DOI: 10.1063\/1.5088169},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {techreport}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('226','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_226\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Data and simulations files for the tutorial article &quot;Brillouin optomechanics in nanophotonic structures&quot;. Published in APL Photonics Special issue \u00d6ptoacoustics\u2014Advances in high-frequency optomechanics and Brillouin scattering&quot; - DOI: 10.1063\/1.5088169<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('226','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_226\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/zenodo.org\/record\/1971811\" title=\"https:\/\/zenodo.org\/record\/1971811\" target=\"_blank\">https:\/\/zenodo.org\/record\/1971811<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.5281\/zenodo.1971811\" title=\"Follow DOI:10.5281\/zenodo.1971811\" target=\"_blank\">doi:10.5281\/zenodo.1971811<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('226','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_2018\">2018<\/h3><h3 class=\"tp_h3\" id=\"tp_h3_article\">Journal Articles<\/h3><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Princepe, Debora;  Wiederhecker, Gustavo S;  Favero, Ivan;  Frateschi, Newton C<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('207','tp_links')\" style=\"cursor:pointer;\">Self-Sustained Laser Pulsation in Active Optomechanical Devices<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">IEEE PHOTONICS JOURNAL, <\/span><span class=\"tp_pub_additional_volume\">vol. 10, <\/span><span class=\"tp_pub_additional_number\">no. 3, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 1943-0655<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_207\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('207','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_207\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('207','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_207\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('207','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_207\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{ISI:000432841700001,<br \/>\r\ntitle = {Self-Sustained Laser Pulsation in Active Optomechanical Devices},<br \/>\r\nauthor = {Debora Princepe and Gustavo S Wiederhecker and Ivan Favero and Newton C Frateschi},<br \/>\r\ndoi = {10.1109\/JPHOT.2018.2831001},<br \/>\r\nissn = {1943-0655},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-06-01},<br \/>\r\njournal = {IEEE PHOTONICS JOURNAL},<br \/>\r\nvolume = {10},<br \/>\r\nnumber = {3},<br \/>\r\npublisher = {IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC},<br \/>\r\naddress = {445 HOES LANE, PISCATAWAY, NJ 08855-4141 USA},<br \/>\r\nabstract = {We developed a model for an active optomechanical cavity embedding a <br \/>\r\n semiconductor optical gain medium in the presence of dispersive and <br \/>\r\n dissipative optomechanical couplings. Radiation pressure drives the <br \/>\r\n mechanical oscillation and the back-action occurs due to the mechanical <br \/>\r\n modulation of the cavity loss rate. Our numerical analysis utilizing <br \/>\r\n this model shows that, even in a wideband gain material, such mechanism <br \/>\r\n couples the mechanical vibration with the laser relaxation oscillation, <br \/>\r\n enabling an effect of self-pulsed laser emission. In order to <br \/>\r\n investigate this effect, we propose a bullseye-shaped device with high <br \/>\r\n confinement of both the optical and the mechanical modes at the edge of <br \/>\r\n a disk combined with a dissipative structure in its vicinity. The <br \/>\r\n dispersive interaction is promoted by the strong photoelastic effect <br \/>\r\n while the dissipative mechanism is governed by the boundary motion <br \/>\r\n mechanism, enhanced by near-field interaction with the absorptive <br \/>\r\n structure. This hybrid optomechanical device is shown to lead sufficient <br \/>\r\n coupling for the experimental demonstration of the self-pulsed emission.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('207','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_207\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We developed a model for an active optomechanical cavity embedding a <br \/>\r\n semiconductor optical gain medium in the presence of dispersive and <br \/>\r\n dissipative optomechanical couplings. Radiation pressure drives the <br \/>\r\n mechanical oscillation and the back-action occurs due to the mechanical <br \/>\r\n modulation of the cavity loss rate. Our numerical analysis utilizing <br \/>\r\n this model shows that, even in a wideband gain material, such mechanism <br \/>\r\n couples the mechanical vibration with the laser relaxation oscillation, <br \/>\r\n enabling an effect of self-pulsed laser emission. In order to <br \/>\r\n investigate this effect, we propose a bullseye-shaped device with high <br \/>\r\n confinement of both the optical and the mechanical modes at the edge of <br \/>\r\n a disk combined with a dissipative structure in its vicinity. The <br \/>\r\n dispersive interaction is promoted by the strong photoelastic effect <br \/>\r\n while the dissipative mechanism is governed by the boundary motion <br \/>\r\n mechanism, enhanced by near-field interaction with the absorptive <br \/>\r\n structure. This hybrid optomechanical device is shown to lead sufficient <br \/>\r\n coupling for the experimental demonstration of the self-pulsed emission.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('207','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_207\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1109\/JPHOT.2018.2831001\" title=\"Follow DOI:10.1109\/JPHOT.2018.2831001\" target=\"_blank\">doi:10.1109\/JPHOT.2018.2831001<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('207','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, Mario C M M;  Grieco, Andrew;  Frateschi, Newton C;  Fainman, Yeshaiahu<\/p><p class=\"tp_pub_title\"><a href=\"https:\/\/sites.ifi.unicamp.br\/lpd\/fourier-transform-spectrometer-on-silicon-with-thermo-optic-non-linearity-and-dispersion-correction-5\/\">Fourier transform spectrometer on silicon with thermo-optic  non-linearity and dispersion correction<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">NATURE COMMUNICATIONS, <\/span><span class=\"tp_pub_additional_volume\">vol. 9, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2041-1723<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_208\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('208','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_208\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('208','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_208\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('208','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_208\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Souza2018,<br \/>\r\ntitle = {Fourier transform spectrometer on silicon with thermo-optic  non-linearity and dispersion correction},<br \/>\r\nauthor = {Mario C M M Souza and Andrew Grieco and Newton C Frateschi and Yeshaiahu Fainman},<br \/>\r\nurl = {https:\/\/doi.org\/10.1038\/s41467-018-03004-6},<br \/>\r\ndoi = {10.1038\/s41467-018-03004-6},<br \/>\r\nissn = {2041-1723},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-02-01},<br \/>\r\njournal = {NATURE COMMUNICATIONS},<br \/>\r\nvolume = {9},<br \/>\r\npublisher = {NATURE PUBLISHING GROUP},<br \/>\r\naddress = {MACMILLAN BUILDING, 4 CRINAN ST, LONDON N1 9XW, ENGLAND},<br \/>\r\nabstract = {Miniaturized integrated spectrometers will have unprecedented impact on <br \/>\r\n applications ranging from unmanned aerial vehicles to mobile phones, and <br \/>\r\n silicon photonics promises to deliver compact, cost-effective devices. <br \/>\r\n Mirroring its ubiquitous free-space counterpart, a silicon <br \/>\r\n photonics-based Fourier transform spectrometer (Si-FTS) can bring <br \/>\r\n broadband operation and fine resolution to the chip scale. Here we <br \/>\r\n present the modeling and experimental demonstration of a thermally tuned <br \/>\r\n Si-FTS accounting for dispersion, thermo-optic non-linearity, and <br \/>\r\n thermal expansion. We show how these effects modify the relation between <br \/>\r\n the spectrum and interferogram of a light source and we develop a <br \/>\r\n quantitative correction procedure through calibration with a tunable <br \/>\r\n laser. We retrieve a broadband spectrum (7 THz around 193.4 THz with <br \/>\r\n 0.38-THz resolution consuming 2.5W per heater) and demonstrate the <br \/>\r\n Si-FTS resilience to fabrication variations - a major advantage for <br \/>\r\n large-scale manufacturing. Providing design flexibility and robustness, <br \/>\r\n the Si-FTS is poised to become a fundamental building block for on-chip <br \/>\r\n spectroscopy.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('208','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_208\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Miniaturized integrated spectrometers will have unprecedented impact on <br \/>\r\n applications ranging from unmanned aerial vehicles to mobile phones, and <br \/>\r\n silicon photonics promises to deliver compact, cost-effective devices. <br \/>\r\n Mirroring its ubiquitous free-space counterpart, a silicon <br \/>\r\n photonics-based Fourier transform spectrometer (Si-FTS) can bring <br \/>\r\n broadband operation and fine resolution to the chip scale. Here we <br \/>\r\n present the modeling and experimental demonstration of a thermally tuned <br \/>\r\n Si-FTS accounting for dispersion, thermo-optic non-linearity, and <br \/>\r\n thermal expansion. We show how these effects modify the relation between <br \/>\r\n the spectrum and interferogram of a light source and we develop a <br \/>\r\n quantitative correction procedure through calibration with a tunable <br \/>\r\n laser. We retrieve a broadband spectrum (7 THz around 193.4 THz with <br \/>\r\n 0.38-THz resolution consuming 2.5W per heater) and demonstrate the <br \/>\r\n Si-FTS resilience to fabrication variations - a major advantage for <br \/>\r\n large-scale manufacturing. Providing design flexibility and robustness, <br \/>\r\n the Si-FTS is poised to become a fundamental building block for on-chip <br \/>\r\n spectroscopy.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('208','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_208\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/doi.org\/10.1038\/s41467-018-03004-6\" title=\"https:\/\/doi.org\/10.1038\/s41467-018-03004-6\" target=\"_blank\">https:\/\/doi.org\/10.1038\/s41467-018-03004-6<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1038\/s41467-018-03004-6\" title=\"Follow DOI:10.1038\/s41467-018-03004-6\" target=\"_blank\">doi:10.1038\/s41467-018-03004-6<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('208','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_inproceedings\">Proceedings Articles<\/h3><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Benevides, Rodrigo;  Carvalho, Nat\u00e1lia C;  M\u00e9nard, Micha\u00ebl;  Frateschi, Newton C;  Wiederhecker, Gustavo S;  Alegre, Thiago P M<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('234','tp_links')\" style=\"cursor:pointer;\">Overcoming optical spring effect with thermo-opto-mechanical coupling in GaAs microdisks<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Latin America Optics and Photonics Conference, <\/span><span class=\"tp_pub_additional_pages\">pp. W4D.4, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_234\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('234','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_234\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('234','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_234\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('234','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_234\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Benevides:18,<br \/>\r\ntitle = {Overcoming optical spring effect with thermo-opto-mechanical coupling in GaAs microdisks},<br \/>\r\nauthor = {Rodrigo Benevides and Nat\u00e1lia C Carvalho and Micha\u00ebl M\u00e9nard and Newton C Frateschi and Gustavo S Wiederhecker and Thiago P M Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W4D.4},<br \/>\r\ndoi = {10.1364\/LAOP.2018.W4D.4},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-01-01},<br \/>\r\nbooktitle = {Latin America Optics and Photonics Conference},<br \/>\r\njournal = {Latin America Optics and Photonics Conference},<br \/>\r\npages = {W4D.4},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We demonstrate a composite coupling between optical fields, acoustic modes and thermal expansion in gallium arsenide microdisks. A relationship between optical detuning and mechanical frequency diverse from traditional optomechanical theory is also observed.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('234','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_234\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate a composite coupling between optical fields, acoustic modes and thermal expansion in gallium arsenide microdisks. A relationship between optical detuning and mechanical frequency diverse from traditional optomechanical theory is also observed.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('234','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_234\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W4D.4\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W4D.4\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W4D.4<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/LAOP.2018.W4D.4\" title=\"Follow DOI:10.1364\/LAOP.2018.W4D.4\" target=\"_blank\">doi:10.1364\/LAOP.2018.W4D.4<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('234','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Wiederhecker, Gustavo S;  Alegre, Thiago Mayer P;  Dainese, Paulo;  Frateschi, Newton C<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('235','tp_links')\" style=\"cursor:pointer;\">Towards fabless optomechanics: enhancing light and sound interaction in a CMOS-complatible platform<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Latin America Optics and Photonics Conference, <\/span><span class=\"tp_pub_additional_pages\">pp. W3E.2, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_235\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('235','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_235\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('235','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_235\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('235','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_235\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Wiederhecker:18,<br \/>\r\ntitle = {Towards fabless optomechanics: enhancing light and sound interaction in a CMOS-complatible platform},<br \/>\r\nauthor = {Gustavo S Wiederhecker and Thiago Mayer P Alegre and Paulo Dainese and Newton C Frateschi},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2},<br \/>\r\ndoi = {10.1364\/LAOP.2018.W3E.2},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-01-01},<br \/>\r\nbooktitle = {Latin America Optics and Photonics Conference},<br \/>\r\njournal = {Latin America Optics and Photonics Conference},<br \/>\r\npages = {W3E.2},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {In this talk we will review our recent efforts in enabling strong interaction between light and mechanical modes using a mixed foundry and in-house fabrication approach.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('235','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_235\" style=\"display:none;\"><div class=\"tp_abstract_entry\">In this talk we will review our recent efforts in enabling strong interaction between light and mechanical modes using a mixed foundry and in-house fabrication approach.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('235','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_235\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2018-W3E.2<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/LAOP.2018.W3E.2\" title=\"Follow DOI:10.1364\/LAOP.2018.W3E.2\" target=\"_blank\">doi:10.1364\/LAOP.2018.W3E.2<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('235','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Santos, La\u00eds F;  Inga, Marvyn;  Soares, Jorge H;  Alegre, Mayer T P;  Wiederhecker, G S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('236','tp_links')\" style=\"cursor:pointer;\">Dispersion Control in Silicon Oxide Wedge Microdisks<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JTu2A.111, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2018<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_236\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('236','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_236\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('236','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_236\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('236','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_236\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Santos:18,<br \/>\r\ntitle = {Dispersion Control in Silicon Oxide Wedge Microdisks},<br \/>\r\nauthor = {La\u00eds F Santos and Marvyn Inga and Jorge H Soares and Mayer T P Alegre and G S Wiederhecker},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111},<br \/>\r\ndoi = {10.1364\/CLEO_AT.2018.JTu2A.111},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JTu2A.111},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We demonstrate the generation of optical frequency combs by engineering the dispersion of a small radius (100 microns) thin wedge microcavity. The phase-matching of the excitation taper is also employed to inhibit avoided-crossings.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('236','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_236\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate the generation of optical frequency combs by engineering the dispersion of a small radius (100 microns) thin wedge microcavity. The phase-matching of the excitation taper is also employed to inhibit avoided-crossings.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('236','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_236\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2018-JTu2A.111<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_AT.2018.JTu2A.111\" title=\"Follow DOI:10.1364\/CLEO_AT.2018.JTu2A.111\" target=\"_blank\">doi:10.1364\/CLEO_AT.2018.JTu2A.111<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('236','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_mastersthesis\">Masters Theses<\/h3><div class=\"tp_publication tp_publication_mastersthesis\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Fujii, Lais<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('227','tp_links')\" style=\"cursor:pointer;\">Dispersion engineering and frequency comb generation in silicon oxide wedge microdisks<\/a> <span class=\"tp_pub_type tp_  mastersthesis\">Masters Thesis<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_school\">[s.n.], <\/span><span class=\"tp_pub_additional_year\">2018<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_227\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('227','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_227\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('227','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_227\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('227','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_227\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@mastersthesis{Fujii:wv,<br \/>\r\ntitle = {Dispersion engineering and frequency comb generation in silicon oxide wedge microdisks},<br \/>\r\nauthor = {Lais Fujii},<br \/>\r\nurl = {http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/332249},<br \/>\r\nyear  = {2018},<br \/>\r\ndate = {2018-01-01},<br \/>\r\npublisher = {[s.n.]},<br \/>\r\nschool = {[s.n.]},<br \/>\r\nabstract = {Resumo: A gerac c~ao de pentes de frequ^encia tem sido um campo ativo de pesquisa, com aplicac c~oes indo de metrologia a astronomia, passando por espectroscopia e medidas de dist^ancia mais precisas. Um dos principais m\u00e9todos de gerac c~ao de pentes \u00e9 por meio de mistura de quatro ondas, um processo n~ao-linear de terceira ordem no qual um par de f\u00f3tons \u00e9 substitu'ido por outro par com novas frequ^encias (conservando energia e momento). A alta intensidade \u00f3ptica necess\u00e1ria para o desencadeamento deste processo \u00e9 obtida atrav\u00e9s da intensificac c~ao ressonante do campo eletromagn\u00e9tico no interior de uma microcavidade, que confina a luz em pequenos volumes e reduz a pot^encia de entrada. Al\u00e9m da vantagem energ\u00e9tica e do potencial para miniaturizac c~ao e produc c~ao em larga escala, essa plataforma possibilita a customizac c~ao de par^ametros do pente de frequ^encia: a taxa de repetic c~ao do pente escala com o inverso do raio da cavidade, pois as bandas laterais criadas devem coincidir com as frequ^encias harm^onicas do dispositivo. A largura de banda do pente tamb\u00e9m pode ser controlada com um planejamento cuidadoso da geometria do dispositivo, pois \u00e9 limitada em grande parte pela variac c~ao do intervalo espectral livre com a frequ^encia. Nesta dissertac c~ao, estudamos como a dispers~ao modal de um microdisco de \u00f3xido de sil'icio em forma de cunha \u00e9 modificada por mudanc cas em suas caracter'isticas geom\u00e9tricas. Para tanto, desenvolvemos a habilidade de controlar o ^angulo dos dispositivos fabricados e de medir a dispers~ao do modo fundamental a partir de seus espectros de transmiss~ao. Os resultados (corroborados por simulac c~oes num\u00e9ricas) mostram que a dispers~ao (em 1550 nm) vai de normal a an^omala com o aumento do ^angulo. Ainda, utilizamos os dispositivos fabricados para gerar pentes de frequ^encia no regime de dispers~ao an^omala e concluimos que a din^amica de formac c~ao \u00e9 bem descrita pelo formalismo de expans~ao modal},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {mastersthesis}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('227','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_227\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Resumo: A gerac c~ao de pentes de frequ^encia tem sido um campo ativo de pesquisa, com aplicac c~oes indo de metrologia a astronomia, passando por espectroscopia e medidas de dist^ancia mais precisas. Um dos principais m\u00e9todos de gerac c~ao de pentes \u00e9 por meio de mistura de quatro ondas, um processo n~ao-linear de terceira ordem no qual um par de f\u00f3tons \u00e9 substitu'ido por outro par com novas frequ^encias (conservando energia e momento). A alta intensidade \u00f3ptica necess\u00e1ria para o desencadeamento deste processo \u00e9 obtida atrav\u00e9s da intensificac c~ao ressonante do campo eletromagn\u00e9tico no interior de uma microcavidade, que confina a luz em pequenos volumes e reduz a pot^encia de entrada. Al\u00e9m da vantagem energ\u00e9tica e do potencial para miniaturizac c~ao e produc c~ao em larga escala, essa plataforma possibilita a customizac c~ao de par^ametros do pente de frequ^encia: a taxa de repetic c~ao do pente escala com o inverso do raio da cavidade, pois as bandas laterais criadas devem coincidir com as frequ^encias harm^onicas do dispositivo. A largura de banda do pente tamb\u00e9m pode ser controlada com um planejamento cuidadoso da geometria do dispositivo, pois \u00e9 limitada em grande parte pela variac c~ao do intervalo espectral livre com a frequ^encia. Nesta dissertac c~ao, estudamos como a dispers~ao modal de um microdisco de \u00f3xido de sil'icio em forma de cunha \u00e9 modificada por mudanc cas em suas caracter'isticas geom\u00e9tricas. Para tanto, desenvolvemos a habilidade de controlar o ^angulo dos dispositivos fabricados e de medir a dispers~ao do modo fundamental a partir de seus espectros de transmiss~ao. Os resultados (corroborados por simulac c~oes num\u00e9ricas) mostram que a dispers~ao (em 1550 nm) vai de normal a an^omala com o aumento do ^angulo. Ainda, utilizamos os dispositivos fabricados para gerar pentes de frequ^encia no regime de dispers~ao an^omala e concluimos que a din^amica de formac c~ao \u00e9 bem descrita pelo formalismo de expans~ao modal<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('227','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_227\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/332249\" title=\"http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/332249\" target=\"_blank\">http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/332249<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('227','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_2017\">2017<\/h3><h3 class=\"tp_h3\" id=\"tp_h3_article\">Journal Articles<\/h3><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Luiz, Gustavo O;  Benevides, Rodrigo S;  Santos, Felipe G S;  Espinel, Yovanny A V;  Alegre, Thiago Mayer P;  Wiederhecker, Gustavo S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('206','tp_links')\" style=\"cursor:pointer;\">Efficient anchor loss suppression in coupled near-field optomechanical resonators<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Opt. Express, <\/span><span class=\"tp_pub_additional_volume\">vol. 25, <\/span><span class=\"tp_pub_additional_number\">no. 25, <\/span><span class=\"tp_pub_additional_pages\">pp. 31347\u201331361, <\/span><span class=\"tp_pub_additional_year\">2017<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_206\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('206','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_206\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('206','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_206\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('206','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_206\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Luiz:17,<br \/>\r\ntitle = {Efficient anchor loss suppression in coupled near-field optomechanical resonators},<br \/>\r\nauthor = {Gustavo O Luiz and Rodrigo S Benevides and Felipe G S Santos and Yovanny A V Espinel and Thiago Mayer P Alegre and Gustavo S Wiederhecker},<br \/>\r\nurl = {http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-25-31347},<br \/>\r\ndoi = {10.1364\/OE.25.031347},<br \/>\r\nyear  = {2017},<br \/>\r\ndate = {2017-12-01},<br \/>\r\njournal = {Opt. Express},<br \/>\r\nvolume = {25},<br \/>\r\nnumber = {25},<br \/>\r\npages = {31347--31361},<br \/>\r\npublisher = {OSA},<br \/>\r\nabstract = {Elastic dissipation through radiation towards the substrate is a major loss channel in micro- and nanomechanical resonators. Engineering the coupling of these resonators with optical cavities further complicates and constrains the design of low-loss optomechanical devices. In this work we rely on the coherent cancellation of mechanical radiation to demonstrate material and surface absorption limited silicon near-field optomechanical resonators oscillating at tens of MHz. The effectiveness of our dissipation suppression scheme is investigated at room and cryogenic temperatures. While at room temperature we can reach a maximum quality factor of 7.61k (fQ-product of the order of 1011 Hz), at 22 K the quality factor increases to 37k, resulting in a fQ-product of 2 &#x000D7; 1012 Hz.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('206','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_206\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Elastic dissipation through radiation towards the substrate is a major loss channel in micro- and nanomechanical resonators. Engineering the coupling of these resonators with optical cavities further complicates and constrains the design of low-loss optomechanical devices. In this work we rely on the coherent cancellation of mechanical radiation to demonstrate material and surface absorption limited silicon near-field optomechanical resonators oscillating at tens of MHz. The effectiveness of our dissipation suppression scheme is investigated at room and cryogenic temperatures. While at room temperature we can reach a maximum quality factor of 7.61k (fQ-product of the order of 1011 Hz), at 22 K the quality factor increases to 37k, resulting in a fQ-product of 2 &amp;#x000D7; 1012 Hz.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('206','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_206\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-25-31347\" title=\"http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-25-31347\" target=\"_blank\">http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-25-31347<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OE.25.031347\" title=\"Follow DOI:10.1364\/OE.25.031347\" target=\"_blank\">doi:10.1364\/OE.25.031347<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('206','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Davis, Jordan A;  Grieco, Andrew;  Souza, Mario C M M;  Frateschi, Newton C;  Fainman, Yeshaiahu<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('209','tp_links')\" style=\"cursor:pointer;\">Hybrid multimode resonators based on grating-assisted \r\n counter-directional couplers<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">OPTICS EXPRESS, <\/span><span class=\"tp_pub_additional_volume\">vol. 25, <\/span><span class=\"tp_pub_additional_number\">no. 14, <\/span><span class=\"tp_pub_additional_pages\">pp. 16484-16490, <\/span><span class=\"tp_pub_additional_year\">2017<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 1094-4087<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_209\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('209','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_209\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('209','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_209\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('209','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_209\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{ISI:000407815100078,<br \/>\r\ntitle = {Hybrid multimode resonators based on grating-assisted <br \/>\r\n counter-directional couplers},<br \/>\r\nauthor = {Jordan A Davis and Andrew Grieco and Mario C M M Souza and Newton C Frateschi and Yeshaiahu Fainman},<br \/>\r\ndoi = {10.1364\/OE.25.016484},<br \/>\r\nissn = {1094-4087},<br \/>\r\nyear  = {2017},<br \/>\r\ndate = {2017-07-01},<br \/>\r\njournal = {OPTICS EXPRESS},<br \/>\r\nvolume = {25},<br \/>\r\nnumber = {14},<br \/>\r\npages = {16484-16490},<br \/>\r\npublisher = {OPTICAL SOC AMER},<br \/>\r\naddress = {2010 MASSACHUSETTS AVE NW, WASHINGTON, DC 20036 USA},<br \/>\r\nabstract = {Research thrusts in silicon photonics are developing control operations <br \/>\r\n using higher order waveguide modes for next generation high-bandwidth <br \/>\r\n communication systems. In this context, devices allowing optical <br \/>\r\n processing of multiple waveguide modes can reduce architecture <br \/>\r\n complexity and enable flexible on-chip networks. We propose and <br \/>\r\n demonstrate a hybrid resonator dually resonant at the 1st and 2nd order <br \/>\r\n modes of a silicon waveguide. We observe 8 dB extinction ratio and modal <br \/>\r\n conversion range of 20 nm for the 1st order quasi-TE mode input. (C) <br \/>\r\n 2017 Optical Society of America},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('209','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_209\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Research thrusts in silicon photonics are developing control operations <br \/>\r\n using higher order waveguide modes for next generation high-bandwidth <br \/>\r\n communication systems. In this context, devices allowing optical <br \/>\r\n processing of multiple waveguide modes can reduce architecture <br \/>\r\n complexity and enable flexible on-chip networks. We propose and <br \/>\r\n demonstrate a hybrid resonator dually resonant at the 1st and 2nd order <br \/>\r\n modes of a silicon waveguide. We observe 8 dB extinction ratio and modal <br \/>\r\n conversion range of 20 nm for the 1st order quasi-TE mode input. (C) <br \/>\r\n 2017 Optical Society of America<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('209','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_209\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OE.25.016484\" title=\"Follow DOI:10.1364\/OE.25.016484\" target=\"_blank\">doi:10.1364\/OE.25.016484<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('209','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Espinel, Y. A. V.;  Santos, F. G. S.;  Luiz, G. O.;  Alegre, T. P. Mayer;  Wiederhecker, G. S.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('133','tp_links')\" style=\"cursor:pointer;\">Brillouin Optomechanics in Coupled Silicon Microcavities<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Scientific Reports, <\/span><span class=\"tp_pub_additional_volume\">vol. 7, <\/span><span class=\"tp_pub_additional_pages\">pp. 43423 EP -, <\/span><span class=\"tp_pub_additional_year\">2017<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_resource_link\"><a id=\"tp_links_sh_133\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('133','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_133\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('133','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_133\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Espinel:2017aa,<br \/>\r\ntitle = {Brillouin Optomechanics in Coupled Silicon Microcavities},<br \/>\r\nauthor = {Espinel, Y. A. V. and Santos, F. G. S. and Luiz, G. O. and Alegre, T. P. Mayer and Wiederhecker, G. S.},<br \/>\r\nurl = {http:\/\/dx.doi.org\/10.1038\/srep43423<br \/>\r\nhttps:\/\/arxiv.org\/abs\/1609.09509},<br \/>\r\nyear  = {2017},<br \/>\r\ndate = {2017-03-06},<br \/>\r\njournal = {Scientific Reports},<br \/>\r\nvolume = {7},<br \/>\r\npages = {43423 EP -},<br \/>\r\npublisher = {The Author(s) SN -},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('133','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_133\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/dx.doi.org\/10.1038\/srep43423\" title=\"http:\/\/dx.doi.org\/10.1038\/srep43423\" target=\"_blank\">http:\/\/dx.doi.org\/10.1038\/srep43423<\/a><\/li><li><i class=\"ai ai-arxiv\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/arxiv.org\/abs\/1609.09509\" title=\"https:\/\/arxiv.org\/abs\/1609.09509\" target=\"_blank\">https:\/\/arxiv.org\/abs\/1609.09509<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('133','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Santos, Felipe G. S.;  Espinel, Yovanny A. V.;  Luiz, Gustavo O.;  Benevides, Rodrigo S.;  Wiederhecker, Gustavo S.;  Alegre, Thiago P. Mayer<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('147','tp_links')\" style=\"cursor:pointer;\">Hybrid confinement of optical and mechanical modes in a bullseye optomechanical resonator<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Opt. Express, <\/span><span class=\"tp_pub_additional_volume\">vol. 25, <\/span><span class=\"tp_pub_additional_number\">no. 2, <\/span><span class=\"tp_pub_additional_pages\">pp. 508\u2013529, <\/span><span class=\"tp_pub_additional_year\">2017<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_147\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('147','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_147\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('147','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_147\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('147','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_147\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Santos:17,<br \/>\r\ntitle = {Hybrid confinement of optical and mechanical modes in a bullseye optomechanical resonator},<br \/>\r\nauthor = {Felipe G. S. Santos and Yovanny A. V. Espinel and Gustavo O. Luiz and Rodrigo S. Benevides and Gustavo S. Wiederhecker and Thiago P. Mayer Alegre},<br \/>\r\nurl = {http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-2-508<br \/>\r\nhttps:\/\/arxiv.org\/abs\/1605.06318},<br \/>\r\ndoi = {10.1364\/OE.25.000508},<br \/>\r\nyear  = {2017},<br \/>\r\ndate = {2017-01-01},<br \/>\r\njournal = {Opt. Express},<br \/>\r\nvolume = {25},<br \/>\r\nnumber = {2},<br \/>\r\npages = {508--529},<br \/>\r\npublisher = {OSA},<br \/>\r\nabstract = {Optomechanical cavities have proven to be an exceptional tool to explore fundamental and applied aspects of the interaction between mechanical and optical waves. Here we demonstrate a novel optomechanical cavity based on a disk with a radial mechanical bandgap. This design confines light and mechanical waves through distinct physical mechanisms which allows for independent control of the mechanical and optical properties. Simulations foresee an optomechanical coupling rate g0 reaching 2&#x003C0; &#x000D7; 100 kHz for mechanical frequencies around 5 GHz as well as anchor loss suppression of 60 dB. Our device design is not limited by unique material properties and could be easily adapted to allow for large optomechanical coupling and high mechanical quality factors with other promising materials. Finally, our devices were fabricated in a commercial silicon photonics facility, demonstrating g0\/2&#x003C0; $=$ 23 kHz for mechanical modes with frequencies around 2 GHz and mechanical Q-factors as high as 2300 at room temperature, also showing that our approach can be easily scalable and useful as a new platform for multimode optomechanics.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('147','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_147\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Optomechanical cavities have proven to be an exceptional tool to explore fundamental and applied aspects of the interaction between mechanical and optical waves. Here we demonstrate a novel optomechanical cavity based on a disk with a radial mechanical bandgap. This design confines light and mechanical waves through distinct physical mechanisms which allows for independent control of the mechanical and optical properties. Simulations foresee an optomechanical coupling rate g0 reaching 2&amp;#x003C0; &amp;#x000D7; 100 kHz for mechanical frequencies around 5 GHz as well as anchor loss suppression of 60 dB. Our device design is not limited by unique material properties and could be easily adapted to allow for large optomechanical coupling and high mechanical quality factors with other promising materials. Finally, our devices were fabricated in a commercial silicon photonics facility, demonstrating g0\/2&amp;#x003C0; $=$ 23 kHz for mechanical modes with frequencies around 2 GHz and mechanical Q-factors as high as 2300 at room temperature, also showing that our approach can be easily scalable and useful as a new platform for multimode optomechanics.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('147','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_147\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-2-508\" title=\"http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-2-508\" target=\"_blank\">http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-25-2-508<\/a><\/li><li><i class=\"ai ai-arxiv\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/arxiv.org\/abs\/1605.06318\" title=\"https:\/\/arxiv.org\/abs\/1605.06318\" target=\"_blank\">https:\/\/arxiv.org\/abs\/1605.06318<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OE.25.000508\" title=\"Follow DOI:10.1364\/OE.25.000508\" target=\"_blank\">doi:10.1364\/OE.25.000508<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('147','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Benevides, Rodrigo;  Santos, Felipe G. S.;  Luiz, Gustavo O.;  Wiederhecker, Gustavo S.;  Alegre, Thiago P. Mayer<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('204','tp_links')\" style=\"cursor:pointer;\">Ultrahigh-Q optomechanical crystal cavities fabricated in a CMOS foundry<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Scientific Reports, <\/span><span class=\"tp_pub_additional_volume\">vol. 7, <\/span><span class=\"tp_pub_additional_number\">no. 1, <\/span><span class=\"tp_pub_additional_pages\">pp. 2491, <\/span><span class=\"tp_pub_additional_year\">2017<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 2045-2322<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_204\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('204','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_204\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('204','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_204\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('204','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_204\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Benevides:2017aa,<br \/>\r\ntitle = {Ultrahigh-Q optomechanical crystal cavities fabricated in a CMOS foundry},<br \/>\r\nauthor = {Benevides, Rodrigo and Santos, Felipe G. S. and Luiz, Gustavo O. and Wiederhecker, Gustavo S. and Alegre, Thiago P. Mayer},<br \/>\r\nurl = {http:\/\/dx.doi.org\/10.1038\/s41598-017-02515-4},<br \/>\r\ndoi = {10.1038\/s41598-017-02515-4},<br \/>\r\nisbn = {2045-2322},<br \/>\r\nyear  = {2017},<br \/>\r\ndate = {2017-01-01},<br \/>\r\njournal = {Scientific Reports},<br \/>\r\nvolume = {7},<br \/>\r\nnumber = {1},<br \/>\r\npages = {2491},<br \/>\r\nabstract = {Photonic crystals use periodic structures to create frequency regions where the optical wave propagation is forbidden, which allows the creation and integration of complex optical functionalities in small footprint devices. Such strategy has also been successfully applied to confine mechanical waves and to explore their interaction with light in the so-called optomechanical cavities. Because of their challenging design, these cavities are traditionally fabricated using dedicated high-resolution electron-beam lithography tools that are inherently slow, limiting this solution to small-scale or research applications. Here we show how to overcome this problem by using a deep-UV photolithography process to fabricate optomechanical crystals in a commercial CMOS foundry. We show that a careful design of the photonic crystals can withstand the limitations of the photolithography process, producing cavities with measured intrinsic optical quality factors as high as Q i = (1.21 $pm$0.02) \u00d7106. Optomechanical crystals are also created using phononic crystals to tightly confine the GHz sound waves within the optical cavity, resulting in a measured vacuum optomechanical coupling rate of g 0 = 2\u03c0\u00d7(91 $pm$4) kHz. Efficient sideband cooling and amplification are also demonstrated since these cavities are in the resolved sideband regime. Further improvements in the design and fabrication process suggest that commercial foundry-based optomechanical cavities could be used for quantum ground-state cooling.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('204','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_204\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Photonic crystals use periodic structures to create frequency regions where the optical wave propagation is forbidden, which allows the creation and integration of complex optical functionalities in small footprint devices. Such strategy has also been successfully applied to confine mechanical waves and to explore their interaction with light in the so-called optomechanical cavities. Because of their challenging design, these cavities are traditionally fabricated using dedicated high-resolution electron-beam lithography tools that are inherently slow, limiting this solution to small-scale or research applications. Here we show how to overcome this problem by using a deep-UV photolithography process to fabricate optomechanical crystals in a commercial CMOS foundry. We show that a careful design of the photonic crystals can withstand the limitations of the photolithography process, producing cavities with measured intrinsic optical quality factors as high as Q i = (1.21 $pm$0.02) \u00d7106. Optomechanical crystals are also created using phononic crystals to tightly confine the GHz sound waves within the optical cavity, resulting in a measured vacuum optomechanical coupling rate of g 0 = 2\u03c0\u00d7(91 $pm$4) kHz. Efficient sideband cooling and amplification are also demonstrated since these cavities are in the resolved sideband regime. Further improvements in the design and fabrication process suggest that commercial foundry-based optomechanical cavities could be used for quantum ground-state cooling.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('204','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_204\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/dx.doi.org\/10.1038\/s41598-017-02515-4\" title=\"http:\/\/dx.doi.org\/10.1038\/s41598-017-02515-4\" target=\"_blank\">http:\/\/dx.doi.org\/10.1038\/s41598-017-02515-4<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1038\/s41598-017-02515-4\" title=\"Follow DOI:10.1038\/s41598-017-02515-4\" target=\"_blank\">doi:10.1038\/s41598-017-02515-4<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('204','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_inproceedings\">Proceedings Articles<\/h3><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Luiz, Gustavo O;  Alegre, Thiago P M;  Wiederhecker, Gustavo S<\/p><p class=\"tp_pub_title\">Synchronization of thermal-carrier oscillations in coupled silicon \r\n microcavities <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">2017 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO), <\/span><span class=\"tp_pub_additional_organization\">IEEE <\/span><span class=\"tp_pub_additional_publisher\">IEEE, <\/span><span class=\"tp_pub_additional_address\">345 E 47TH ST, NEW YORK, NY 10017 USA, <\/span><span class=\"tp_pub_additional_year\">2017<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2160-9020<\/span><span class=\"tp_pub_additional_note\">, (Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, MAY 14-19, \r\n 2017)<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_211\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('211','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_211\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('211','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_211\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{ISI:000427296201163,<br \/>\r\ntitle = {Synchronization of thermal-carrier oscillations in coupled silicon <br \/>\r\n microcavities},<br \/>\r\nauthor = {Gustavo O Luiz and Thiago P M Alegre and Gustavo S Wiederhecker},<br \/>\r\nissn = {2160-9020},<br \/>\r\nyear  = {2017},<br \/>\r\ndate = {2017-01-01},<br \/>\r\nbooktitle = {2017 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO)},<br \/>\r\npublisher = {IEEE},<br \/>\r\naddress = {345 E 47TH ST, NEW YORK, NY 10017 USA},<br \/>\r\norganization = {IEEE},<br \/>\r\nseries = {Conference on Lasers and Electro-Optics},<br \/>\r\nabstract = {We report on the synchronization of thermal-carrier self-sustaining <br \/>\r\n oscillations in coupled silicon microdisks. Time and frequency domain <br \/>\r\n signatures of synchronization are observed.},<br \/>\r\nnote = {Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, MAY 14-19, <br \/>\r\n 2017},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('211','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_211\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We report on the synchronization of thermal-carrier self-sustaining <br \/>\r\n oscillations in coupled silicon microdisks. Time and frequency domain <br \/>\r\n signatures of synchronization are observed.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('211','tp_abstract')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_phdthesis\">PhD Theses<\/h3><div class=\"tp_publication tp_publication_phdthesis\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Santos, Felipe G S<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('229','tp_links')\" style=\"cursor:pointer;\">Cavity optomechanics in silicon disks and nanostructured disks<\/a> <span class=\"tp_pub_type tp_  phdthesis\">PhD Thesis<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_year\">2017<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_229\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('229','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_229\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('229','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_229\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('229','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_229\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@phdthesis{Santos:2017ta,<br \/>\r\ntitle = {Cavity optomechanics in silicon disks and nanostructured disks},<br \/>\r\nauthor = {Felipe G S Santos},<br \/>\r\nurl = {http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/325359},<br \/>\r\nyear  = {2017},<br \/>\r\ndate = {2017-01-01},<br \/>\r\nabstract = {A optomec^anica de cavidades se transformou numa \u00e1rea de estudos muito rica, com aplicac c~oes em interfer^ometros de ondas gravitacionais, fundamentos de mec^anica qu^antica, simulac c~oes qu^anticas, sincronizac c~ao, filtros \u00f3pticos reconfigur\u00e1veis por luz, mem\u00f3rias \u00f3pticastextquestiondownentre diversas outras. Dos muitos dispositivos relatados na literatura, microcavidades integradas em chips s~ao uma alternativa promissora para o estudo de efeitos din^amicos devido `a interac c~ao entre ondas \u00f3pticas e ondas mec^anicas confinadas. Entre as microcavidades, discos e cristais optomec^anicos (baseados em confinamento por bandgaps fot^onico e fon^onico) s~ao dispositivos especialmente promissores e frequentemente estudados, cada um tendo vantagens 'unicas. Nesta tese, unimos a versatilidade dos discos ao confinamento por bandgap numa nova proposta de dispositivo optomec^anico, o bullseye (ingl^es para \u00e4lvo\"). De um lado, produzimos conhecimento local em fabricac c~ao e caracterizac c~ao de discos optomec^anicos de sil'icio, chegando a larguras de linha \u00f3ptica menores que 1 GHz (fator de qualidade da ordem de 105). De outro, mostramos que o bullseye pode superar algumas limitac c~oes dos discos simples com o intuito de alcanc car o chamado regime de banda lateral resolvida, no qual a frequ^encia de resson^ancia mec^anica \u00e9 maior que a largura de linha \u00f3ptica. A partir de simulac c~oes pelo m\u00e9todo dos elementos finitos, compreendemos em profundidade as propriedades optomec^anicas do bullseye, prevendo modos mec^anicos de alta frequ^encia com taxa de acoplamento optomec^anico (medida do desvio da frequ^encia \u00f3ptica devido a flutuac c~oes do estado fundamental mec^anico) de at\u00e9 200 kHz textquestiondown valor igual ao dispositivos considerados estado-da-arte. Por fim, demonstramos experimentalmente as propriedades optomec^anicas do bullseye em amostras fabricadas com processos industriais CMOS, um resultado importante que abre o caminho para aplicac c~oes massivas, tanto comerciais quanto em pesquisa, de cavidades optomec^anicas},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {phdthesis}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('229','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_229\" style=\"display:none;\"><div class=\"tp_abstract_entry\">A optomec^anica de cavidades se transformou numa \u00e1rea de estudos muito rica, com aplicac c~oes em interfer^ometros de ondas gravitacionais, fundamentos de mec^anica qu^antica, simulac c~oes qu^anticas, sincronizac c~ao, filtros \u00f3pticos reconfigur\u00e1veis por luz, mem\u00f3rias \u00f3pticastextquestiondownentre diversas outras. Dos muitos dispositivos relatados na literatura, microcavidades integradas em chips s~ao uma alternativa promissora para o estudo de efeitos din^amicos devido `a interac c~ao entre ondas \u00f3pticas e ondas mec^anicas confinadas. Entre as microcavidades, discos e cristais optomec^anicos (baseados em confinamento por bandgaps fot^onico e fon^onico) s~ao dispositivos especialmente promissores e frequentemente estudados, cada um tendo vantagens 'unicas. Nesta tese, unimos a versatilidade dos discos ao confinamento por bandgap numa nova proposta de dispositivo optomec^anico, o bullseye (ingl^es para \u00e4lvo\"). De um lado, produzimos conhecimento local em fabricac c~ao e caracterizac c~ao de discos optomec^anicos de sil'icio, chegando a larguras de linha \u00f3ptica menores que 1 GHz (fator de qualidade da ordem de 105). De outro, mostramos que o bullseye pode superar algumas limitac c~oes dos discos simples com o intuito de alcanc car o chamado regime de banda lateral resolvida, no qual a frequ^encia de resson^ancia mec^anica \u00e9 maior que a largura de linha \u00f3ptica. A partir de simulac c~oes pelo m\u00e9todo dos elementos finitos, compreendemos em profundidade as propriedades optomec^anicas do bullseye, prevendo modos mec^anicos de alta frequ^encia com taxa de acoplamento optomec^anico (medida do desvio da frequ^encia \u00f3ptica devido a flutuac c~oes do estado fundamental mec^anico) de at\u00e9 200 kHz textquestiondown valor igual ao dispositivos considerados estado-da-arte. Por fim, demonstramos experimentalmente as propriedades optomec^anicas do bullseye em amostras fabricadas com processos industriais CMOS, um resultado importante que abre o caminho para aplicac c~oes massivas, tanto comerciais quanto em pesquisa, de cavidades optomec^anicas<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('229','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_229\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/325359\" title=\"http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/325359\" target=\"_blank\">http:\/\/repositorio.unicamp.br\/jspui\/handle\/REPOSIP\/325359<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('229','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_2016\">2016<\/h3><h3 class=\"tp_h3\" id=\"tp_h3_article\">Journal Articles<\/h3><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Amili, A El;  Souza, M C M M;  Vallini, F;  Frateschi, N C;  Fainman, Y<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('210','tp_links')\" style=\"cursor:pointer;\">Magnetically controllable silicon microring with ferrofluid cladding<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">OPTICS LETTERS, <\/span><span class=\"tp_pub_additional_volume\">vol. 41, <\/span><span class=\"tp_pub_additional_number\">no. 23, <\/span><span class=\"tp_pub_additional_pages\">pp. 5576-5579, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 0146-9592<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_210\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('210','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_210\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('210','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_210\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('210','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_210\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{ISI:000389654000042,<br \/>\r\ntitle = {Magnetically controllable silicon microring with ferrofluid cladding},<br \/>\r\nauthor = {A El Amili and M C M M Souza and F Vallini and N C Frateschi and Y Fainman},<br \/>\r\ndoi = {10.1364\/OL.41.005576},<br \/>\r\nissn = {0146-9592},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-12-01},<br \/>\r\njournal = {OPTICS LETTERS},<br \/>\r\nvolume = {41},<br \/>\r\nnumber = {23},<br \/>\r\npages = {5576-5579},<br \/>\r\npublisher = {OPTICAL SOC AMER},<br \/>\r\naddress = {2010 MASSACHUSETTS AVE NW, WASHINGTON, DC 20036 USA},<br \/>\r\nabstract = {We experimentally investigate the application of magnetic fluids (MFs) <br \/>\r\n on integrated silicon photonics. Using a ferro-fluid-clad silicon <br \/>\r\n microring resonator, we demonstrate active control of resonances by <br \/>\r\n applying an external magnetic field. Relatively high loaded quality <br \/>\r\n factors on the order of 6000 are achieved, despite the optical losses <br \/>\r\n introduced by the magnetic nanoparticles. We demonstrate resonance <br \/>\r\n shifts of 185 pm in response to a 110 Oe strong magnetic field, <br \/>\r\n corresponding to an overall refractive index change of -3.2 x 10(-3) for <br \/>\r\n the cladding MF. The combination of MFs and integrated photonics could <br \/>\r\n potentially lead to the development of magnetically controllable optical <br \/>\r\n devices and ultra-compact cost-effective magnetic field sensors. (C) <br \/>\r\n 2016 Optical Society of America},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('210','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_210\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We experimentally investigate the application of magnetic fluids (MFs) <br \/>\r\n on integrated silicon photonics. Using a ferro-fluid-clad silicon <br \/>\r\n microring resonator, we demonstrate active control of resonances by <br \/>\r\n applying an external magnetic field. Relatively high loaded quality <br \/>\r\n factors on the order of 6000 are achieved, despite the optical losses <br \/>\r\n introduced by the magnetic nanoparticles. We demonstrate resonance <br \/>\r\n shifts of 185 pm in response to a 110 Oe strong magnetic field, <br \/>\r\n corresponding to an overall refractive index change of -3.2 x 10(-3) for <br \/>\r\n the cladding MF. The combination of MFs and integrated photonics could <br \/>\r\n potentially lead to the development of magnetically controllable optical <br \/>\r\n devices and ultra-compact cost-effective magnetic field sensors. (C) <br \/>\r\n 2016 Optical Society of America<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('210','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_210\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OL.41.005576\" title=\"Follow DOI:10.1364\/OL.41.005576\" target=\"_blank\">doi:10.1364\/OL.41.005576<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('210','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, Mario C. M. M.;  Rezende, Guilherme F. M.;  Barea, Luis A. M.;  Wiederhecker, Gustavo S.;  Frateschi, Newton C.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('134','tp_links')\" style=\"cursor:pointer;\">Modeling quasi-dark states with temporal coupled-mode theory<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Opt. Express, <\/span><span class=\"tp_pub_additional_volume\">vol. 24, <\/span><span class=\"tp_pub_additional_number\">no. 17, <\/span><span class=\"tp_pub_additional_pages\">pp. 18960\u201318972, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_134\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('134','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_134\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('134','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_134\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('134','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_134\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Souza:2016aa,<br \/>\r\ntitle = {Modeling quasi-dark states with temporal coupled-mode theory},<br \/>\r\nauthor = {Mario C. M. M. Souza and Guilherme F. M. Rezende and Luis A. M. Barea and Gustavo S. Wiederhecker and Newton C. Frateschi},<br \/>\r\nurl = {http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-24-17-18960},<br \/>\r\ndoi = {10.1364\/OE.24.018960},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-08-01},<br \/>\r\njournal = {Opt. Express},<br \/>\r\nvolume = {24},<br \/>\r\nnumber = {17},<br \/>\r\npages = {18960--18972},<br \/>\r\npublisher = {OSA},<br \/>\r\nabstract = {Coupled resonators are commonly used to achieve tailored spectral responses and allow novel functionalities in a broad range of applications. The Temporal Coupled-Mode Theory (TCMT) provides a simple and general tool that is widely used to model these devices. Relying on TCMT to model coupled resonators might however be misleading in some circumstances due to the lumped-element nature of the model. In this article, we report an important limitation of TCMT related to the prediction of dark states. Studying a coupled system composed of three microring resonators, we demonstrate that TCMT predicts the existence of a dark state that is in disagreement with experimental observations and with the more general results obtained with the Transfer Matrix Method (TMM) and the Finite-Difference Time-Domain (FDTD) simulations. We identify the limitation in the TCMT model to be related to the mechanism of excitation\/decay of the supermodes and we propose a correction that effectively reconciles the model with expected results. Our discussion based on coupled microring resonators can be useful for other electromagnetic resonant systems due to the generality and far-reach of the TCMT formalism.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('134','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_134\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Coupled resonators are commonly used to achieve tailored spectral responses and allow novel functionalities in a broad range of applications. The Temporal Coupled-Mode Theory (TCMT) provides a simple and general tool that is widely used to model these devices. Relying on TCMT to model coupled resonators might however be misleading in some circumstances due to the lumped-element nature of the model. In this article, we report an important limitation of TCMT related to the prediction of dark states. Studying a coupled system composed of three microring resonators, we demonstrate that TCMT predicts the existence of a dark state that is in disagreement with experimental observations and with the more general results obtained with the Transfer Matrix Method (TMM) and the Finite-Difference Time-Domain (FDTD) simulations. We identify the limitation in the TCMT model to be related to the mechanism of excitation\/decay of the supermodes and we propose a correction that effectively reconciles the model with expected results. Our discussion based on coupled microring resonators can be useful for other electromagnetic resonant systems due to the generality and far-reach of the TCMT formalism.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('134','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_134\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-24-17-18960\" title=\"http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-24-17-18960\" target=\"_blank\">http:\/\/www.opticsexpress.org\/abstract.cfm?URI=oe-24-17-18960<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OE.24.018960\" title=\"Follow DOI:10.1364\/OE.24.018960\" target=\"_blank\">doi:10.1364\/OE.24.018960<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('134','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Florez, O;  Jarschel, P F;  Espinel, Y A V;  Cordeiro, C M B;  Mayer Alegre, T P;  Wiederhecker, G S;  Dainese, P<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('135','tp_links')\" style=\"cursor:pointer;\">Brillouin scattering self-cancellation<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Nature Communications, <\/span><span class=\"tp_pub_additional_volume\">vol. 7, <\/span><span class=\"tp_pub_additional_pages\">pp. 11759, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_resource_link\"><a id=\"tp_links_sh_135\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('135','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_135\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('135','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_135\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Florez:2016iz,<br \/>\r\ntitle = {Brillouin scattering self-cancellation},<br \/>\r\nauthor = {Florez, O and Jarschel, P F and Espinel, Y A V and Cordeiro, C M B and Mayer Alegre, T P and Wiederhecker, G S and Dainese, P},<br \/>\r\nurl = {http:\/\/www.nature.com\/doifinder\/10.1038\/ncomms11759<br \/>\r\nhttps:\/\/arxiv.org\/abs\/1601.05248},<br \/>\r\ndoi = {10.1038\/ncomms11759},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\njournal = {Nature Communications},<br \/>\r\nvolume = {7},<br \/>\r\npages = {11759},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('135','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_135\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.nature.com\/doifinder\/10.1038\/ncomms11759\" title=\"http:\/\/www.nature.com\/doifinder\/10.1038\/ncomms11759\" target=\"_blank\">http:\/\/www.nature.com\/doifinder\/10.1038\/ncomms11759<\/a><\/li><li><i class=\"ai ai-arxiv\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/arxiv.org\/abs\/1601.05248\" title=\"https:\/\/arxiv.org\/abs\/1601.05248\" target=\"_blank\">https:\/\/arxiv.org\/abs\/1601.05248<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1038\/ncomms11759\" title=\"Follow DOI:10.1038\/ncomms11759\" target=\"_blank\">doi:10.1038\/ncomms11759<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('135','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_inproceedings\">Proceedings Articles<\/h3><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Soares, Jorge H.;  Santos, Felipe G.;  Fujii, Lais;  Wiederhecker, Gustavo S.;  Alegre, Thiago P.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('142','tp_links')\" style=\"cursor:pointer;\">Tunable third-harmonic generation in silicon oxide wedge microcavities<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STh3P.5, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_142\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('142','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_142\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('142','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_142\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('142','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_142\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Soares:2016aa,<br \/>\r\ntitle = {Tunable third-harmonic generation in silicon oxide wedge microcavities},<br \/>\r\nauthor = {Jorge H. Soares and Felipe G. Santos and Lais Fujii and Gustavo S. Wiederhecker and Thiago P. Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STh3P.5},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2016.STh3P.5},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STh3P.5},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We demonstrate tunable third-harmonic generation (THG) using a multimode microcavity. The silicon-oxide wedge-resonator is pumped around 1550 nm telecom band and generates tunable THG (512-520 nm) with a collected power efficiency of 10-5.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('142','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_142\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate tunable third-harmonic generation (THG) using a multimode microcavity. The silicon-oxide wedge-resonator is pumped around 1550 nm telecom band and generates tunable THG (512-520 nm) with a collected power efficiency of 10-5.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('142','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_142\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STh3P.5\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STh3P.5\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STh3P.5<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2016.STh3P.5\" title=\"Follow DOI:10.1364\/CLEO_SI.2016.STh3P.5\" target=\"_blank\">doi:10.1364\/CLEO_SI.2016.STh3P.5<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('142','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\">da Silva Benevides, Rodrigo; de Oliveira Luiz, Gustavo;  Santos, Felipe G.;  Wiederhecker, Gustavo;  Alegre, Thiago P.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('140','tp_links')\" style=\"cursor:pointer;\">Optomechanical Oscillators Fabricated in a CMOS-compatible Foundry<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JTh2A.99, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_140\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('140','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_140\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('140','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_140\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('140','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_140\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{daSilvaBenevides:16,<br \/>\r\ntitle = {Optomechanical Oscillators Fabricated in a CMOS-compatible Foundry},<br \/>\r\nauthor = {Rodrigo da Silva Benevides and Gustavo de Oliveira Luiz and Felipe G. Santos and Gustavo Wiederhecker and Thiago P. Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.99},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JTh2A.99},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We demonstrate self-sustained mechanical oscillations at room temperature and ambient pressure in a silicon photonic crystal slot-cavity fabricated by a CMOS-Foundry. Optical quality factor as high as Qopt$=$4 texttimes 105 and an optomechanical coupling rate of g0\/2$pi$$=$76 kHz are observed.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('140','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_140\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate self-sustained mechanical oscillations at room temperature and ambient pressure in a silicon photonic crystal slot-cavity fabricated by a CMOS-Foundry. Optical quality factor as high as Qopt$=$4 texttimes 105 and an optomechanical coupling rate of g0\/2$pi$$=$76 kHz are observed.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('140','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_140\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.99\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.99\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.99<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('140','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Florez, Omar;  Jarschel, Paulo;  Espinel, Yovanny A.;  Cordeiro, Cristiano M.;  Alegre, Thiago P. Mayer;  Wiederhecker, Gustavo S.;  Dainese, Paulo C.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('141','tp_links')\" style=\"cursor:pointer;\">Theory and Observation of the Brillouin Scattering Self-Cancellation<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Latin America Optics and Photonics Conference, <\/span><span class=\"tp_pub_additional_pages\">pp. LTu5C.1, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_141\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('141','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_141\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('141','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_141\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('141','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_141\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Florez:16,<br \/>\r\ntitle = {Theory and Observation of the Brillouin Scattering Self-Cancellation},<br \/>\r\nauthor = {Omar Florez and Paulo Jarschel and Yovanny A. Espinel and Cristiano M. Cordeiro and Thiago P. Mayer Alegre and Gustavo S. Wiederhecker and Paulo C. Dainese},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2016-LTu5C.1},<br \/>\r\ndoi = {10.1364\/LAOP.2016.LTu5C.1},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {Latin America Optics and Photonics Conference},<br \/>\r\njournal = {Latin America Optics and Photonics Conference},<br \/>\r\npages = {LTu5C.1},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {The Brillouin scattering self-cancellation effect arising from the interplay between the photo-elastic and moving-boundary effects is reviewed. Our recent demonstration of this effect for the fundamental Rayleigh acoustic mode in silica nanowires is also discussed.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('141','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_141\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The Brillouin scattering self-cancellation effect arising from the interplay between the photo-elastic and moving-boundary effects is reviewed. Our recent demonstration of this effect for the fundamental Rayleigh acoustic mode in silica nanowires is also discussed.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('141','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_141\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2016-LTu5C.1\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2016-LTu5C.1\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=LAOP-2016-LTu5C.1<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/LAOP.2016.LTu5C.1\" title=\"Follow DOI:10.1364\/LAOP.2016.LTu5C.1\" target=\"_blank\">doi:10.1364\/LAOP.2016.LTu5C.1<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('141','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, Mario C.;  Rezende, Guilherme;  Barea, Luis;  Wiederhecker, Gustavo;  Frateschi, Newton<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('139','tp_links')\" style=\"cursor:pointer;\">Modifying Coupled Mode Theory to model quasi-dark states in coupled resonators<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. JTh2A.94, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_139\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('139','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_139\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('139','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_139\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('139','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_139\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Souza:2016ab,<br \/>\r\ntitle = {Modifying Coupled Mode Theory to model quasi-dark states in coupled resonators},<br \/>\r\nauthor = {Mario C. Souza and Guilherme Rezende and Luis Barea and Gustavo Wiederhecker and Newton Frateschi},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.94},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {JTh2A.94},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We show that Coupled Mode Theory incorrectly predicts a dark state for a coupled resonator design and we propose a correction that effectively reconciles it with results obtained experimentally and through the Transfer Matrix Method.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('139','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_139\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We show that Coupled Mode Theory incorrectly predicts a dark state for a coupled resonator design and we propose a correction that effectively reconciles it with results obtained experimentally and through the Transfer Matrix Method.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('139','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_139\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.94\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.94\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-JTh2A.94<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('139','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\">de Oliveira Luiz, Gustavo;  Santos, Felipe G.; da Silva Benevides, Rodrigo;  Espinel, Yovanny;  Alegre, Thiago P.;  Wiederhecker, Gustavo<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('138','tp_links')\" style=\"cursor:pointer;\">Material limited high-Q mechanical paddle-resonator<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STu4E.2, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_138\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('138','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_138\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('138','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_138\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('138','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_138\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Oliveira-Luiz:2016aa,<br \/>\r\ntitle = {Material limited high-Q mechanical paddle-resonator},<br \/>\r\nauthor = {Gustavo de Oliveira Luiz and Felipe G. Santos and Rodrigo da Silva Benevides and Yovanny Espinel and Thiago P. Alegre and Gustavo Wiederhecker},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.2},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2016.STu4E.2},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STu4E.2},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We used destructive interference of elastic waves to obtain material limited high quality factor micro mechanical devices probed with an optical cavity. Mechanical quality factors as high as 28texttimes103 were measured.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('138','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_138\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We used destructive interference of elastic waves to obtain material limited high quality factor micro mechanical devices probed with an optical cavity. Mechanical quality factors as high as 28texttimes103 were measured.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('138','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_138\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.2\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.2\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.2<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2016.STu4E.2\" title=\"Follow DOI:10.1364\/CLEO_SI.2016.STu4E.2\" target=\"_blank\">doi:10.1364\/CLEO_SI.2016.STu4E.2<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('138','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Florez, Omar;  Jarschel, Paulo F.;  Espinel, Yovanny A.;  Cordeiro, Cristiano M.;  Alegre, Thiago P.;  Wiederhecker, Gustavo;  Dainese, Paulo C.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('137','tp_links')\" style=\"cursor:pointer;\">Demonstration of Brillouin Scattering Self-Cancellation<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STu3E.6, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_137\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('137','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_137\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('137','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_137\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('137','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_137\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Florez:2016aa,<br \/>\r\ntitle = {Demonstration of Brillouin Scattering Self-Cancellation},<br \/>\r\nauthor = {Omar Florez and Paulo F. Jarschel and Yovanny A. Espinel and Cristiano M. Cordeiro and Thiago P. Alegre and Gustavo Wiederhecker and Paulo C. Dainese},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu3E.6},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2016.STu3E.6},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STu3E.6},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We experimentally demonstrate the cancellation of Brillouin scattering by engineering a sub-wavelength diameter silica wire with exactly opposite photo-elastic and moving-boundary contributions.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('137','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_137\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We experimentally demonstrate the cancellation of Brillouin scattering by engineering a sub-wavelength diameter silica wire with exactly opposite photo-elastic and moving-boundary contributions.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('137','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_137\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu3E.6\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu3E.6\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu3E.6<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2016.STu3E.6\" title=\"Follow DOI:10.1364\/CLEO_SI.2016.STu3E.6\" target=\"_blank\">doi:10.1364\/CLEO_SI.2016.STu3E.6<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('137','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Santos, Felipe G.;  Espinel, Yovanny; de Oliveira Luiz, Gustavo; da Silva Benevides, Rodrigo;  Wiederhecker, Gustavo;  Alegre, Thiago P.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('136','tp_links')\" style=\"cursor:pointer;\">Bullseye Optomechanical Resonator<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Conference on Lasers and Electro-Optics, <\/span><span class=\"tp_pub_additional_pages\">pp. STu4E.4, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_136\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('136','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_136\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('136','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_136\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('136','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_136\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Santos:2016aa,<br \/>\r\ntitle = {Bullseye Optomechanical Resonator},<br \/>\r\nauthor = {Felipe G. Santos and Yovanny Espinel and Gustavo de Oliveira Luiz and Rodrigo da Silva Benevides and Gustavo Wiederhecker and Thiago P. Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.4},<br \/>\r\ndoi = {10.1364\/CLEO_SI.2016.STu4E.4},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {Conference on Lasers and Electro-Optics},<br \/>\r\njournal = {Conference on Lasers and Electro-Optics},<br \/>\r\npages = {STu4E.4},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We demonstrate an optomechanical resonator that can tightly confine phonons through a circular phononic shield. Our design allows for independently trimmable long living optical and mechanical modes with large optomechanical coupling.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('136','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_136\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate an optomechanical resonator that can tightly confine phonons through a circular phononic shield. Our design allows for independently trimmable long living optical and mechanical modes with large optomechanical coupling.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('136','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_136\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.4\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.4\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_SI-2016-STu4E.4<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/CLEO_SI.2016.STu4E.4\" title=\"Follow DOI:10.1364\/CLEO_SI.2016.STu4E.4\" target=\"_blank\">doi:10.1364\/CLEO_SI.2016.STu4E.4<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('136','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Cirino, Giuseppe A;  Barea, Luis A; von Zuben, Antonio A;  L'hermite, Herve;  Beche, Bruno;  Sagazan, Olivier De;  Frateschi, Newton;  M-Brahim, Tayeb<\/p><p class=\"tp_pub_title\">Simulation and Fabrication of Silicon Nitride Microring Resonator by DUV \r\n Lithography <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">2016 31ST SYMPOSIUM ON MICROELECTRONICS TECHNOLOGY AND DEVICES (SBMICRO), <\/span><span class=\"tp_pub_additional_organization\">IEEE; SBA; Brazilian Comp Soc; Electron Devices Soc; ECS; Departamento \r\n Ciencia Computacao; Departamento Engenharia Eletrica; Departamento \r\n Fisica; Univ Fed Minas Gerais, Escola Engenharia; PPGEE; DELT; BNDES; \r\n BRASIL GOVERNO FED; IFIP; CAS; Sociedade Brasileira Fisica; IEEE \r\n Instrumentat &amp; Measurement Soc; Assoc Comp Machinery; IEEE Council \r\n Elect Design Automat; FAPEMIG; Conselho Nacional Desenvolvimento \r\n Cientifico Tecnologico; CAPES; Unitec semicondutores <\/span><span class=\"tp_pub_additional_publisher\">IEEE, <\/span><span class=\"tp_pub_additional_address\">345 E 47TH ST, NEW YORK, NY 10017 USA, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-5090-2788-0<\/span><span class=\"tp_pub_additional_note\">, (31st Symposium on Microelectronics Technology and Devices (SBMicro), \r\n Belo Horizonte, BRAZIL, AUG 29-SEP 03, 2016)<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_221\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('221','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_221\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('221','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_221\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{ISI:000392469000033,<br \/>\r\ntitle = {Simulation and Fabrication of Silicon Nitride Microring Resonator by DUV <br \/>\r\n Lithography},<br \/>\r\nauthor = {Giuseppe A Cirino and Luis A Barea and Antonio A von Zuben and Herve L'hermite and Bruno Beche and Olivier De Sagazan and Newton Frateschi and Tayeb M-Brahim},<br \/>\r\nisbn = {978-1-5090-2788-0},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\nbooktitle = {2016 31ST SYMPOSIUM ON MICROELECTRONICS TECHNOLOGY AND DEVICES (SBMICRO)},<br \/>\r\npublisher = {IEEE},<br \/>\r\naddress = {345 E 47TH ST, NEW YORK, NY 10017 USA},<br \/>\r\norganization = {IEEE; SBA; Brazilian Comp Soc; Electron Devices Soc; ECS; Departamento <br \/>\r\n Ciencia Computacao; Departamento Engenharia Eletrica; Departamento <br \/>\r\n Fisica; Univ Fed Minas Gerais, Escola Engenharia; PPGEE; DELT; BNDES; <br \/>\r\n BRASIL GOVERNO FED; IFIP; CAS; Sociedade Brasileira Fisica; IEEE <br \/>\r\n Instrumentat & Measurement Soc; Assoc Comp Machinery; IEEE Council <br \/>\r\n Elect Design Automat; FAPEMIG; Conselho Nacional Desenvolvimento <br \/>\r\n Cientifico Tecnologico; CAPES; Unitec semicondutores},<br \/>\r\nabstract = {This work reports the design and fabrication of silicon nitride-based <br \/>\r\n microresonators by employing DUV optical lithography and ICP-RIE plasma <br \/>\r\n etching. Microring devices with high Q factors provide high sensitivity <br \/>\r\n and low detection limit, enabling their use in biochemical sensing <br \/>\r\n applications. With these properties, the devices can be used to detect <br \/>\r\n and quantify the biomolecules present in a homogeneous solution, by <br \/>\r\n detecting an effective refractive index change, without using <br \/>\r\n fluorescent labels.},<br \/>\r\nnote = {31st Symposium on Microelectronics Technology and Devices (SBMicro), <br \/>\r\n Belo Horizonte, BRAZIL, AUG 29-SEP 03, 2016},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('221','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_221\" style=\"display:none;\"><div class=\"tp_abstract_entry\">This work reports the design and fabrication of silicon nitride-based <br \/>\r\n microresonators by employing DUV optical lithography and ICP-RIE plasma <br \/>\r\n etching. Microring devices with high Q factors provide high sensitivity <br \/>\r\n and low detection limit, enabling their use in biochemical sensing <br \/>\r\n applications. With these properties, the devices can be used to detect <br \/>\r\n and quantify the biomolecules present in a homogeneous solution, by <br \/>\r\n detecting an effective refractive index change, without using <br \/>\r\n fluorescent labels.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('221','tp_abstract')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_mastersthesis\">Masters Theses<\/h3><div class=\"tp_publication tp_publication_mastersthesis\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Benevides, Rodrigo S<\/p><p class=\"tp_pub_title\">Optomechanics in photonic crystal cavities <span class=\"tp_pub_type tp_  mastersthesis\">Masters Thesis<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_address\">Campinas, <\/span><span class=\"tp_pub_additional_year\">2016<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_228\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('228','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_228\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('228','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_228\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@mastersthesis{Benevides:2016uw,<br \/>\r\ntitle = {Optomechanics in photonic crystal cavities},<br \/>\r\nauthor = {Rodrigo S Benevides},<br \/>\r\nyear  = {2016},<br \/>\r\ndate = {2016-01-01},<br \/>\r\naddress = {Campinas},<br \/>\r\nabstract = {The field of cavity optomechanics has experienced a rapid growth in last decade. The increasing interest in this area was mostly driven by the intricate interface between mechanical motion and the optical field. Such coupling is widely explored in a variety of experiments scaling from kilometer long interferometers to micrometer optical cavities. The challenge on all these experiments is to create an optomechanical device with long-living optical and mechanical resonances while keeping a large coupling rate. In this context photonic crystal cavities have emerged as a strong candidate since they are able to produce very small optical mode volume and long optical lifetime. In the classical regime, these tiny devices, which can mechanically oscillate from frequencies ranging from couple MHz up to tens of GHz, allows for highly sensitive small forces, masses, displacements and acceleration detectors. They are also used to produce high quality optically driven mechanical oscillators which can be synchronized via an optical field. In the quantum regime, cavity quantum optomechanics is being used to understand decoherence phenomena in a mesoscopic scale by creating nonclassical states between light and mechanical modes intermediated by optomechanical interaction. However up to now, few studies have been done concerning the possibility of large scale production of these devices, a necessary step towards massive technological and scientific application of these devices. <br \/>\r\nIn this work, we describe a detailed study of optomechanical cavities based upon photonic crystal cavities fabricated in a CMOS-compatible commercial foundry. We prove the feasibil- ity of this platform exploring three photonic crystal designs. First, we show how to achieve ultra-high optical quality factors using a design resilient to the fabrication constrains. Our demonstrated quality factors are the largest ever reported using photonic crystal cavities man- ufactured by optical lithography. Secondly, we investigate a slot type optical cavity, able to produce very large optomechanical coupling using a simple in-plane motion. Finally, we design a trimmable acoustic shield to restrict the mechanical motion inside the optical region. Such strategy was successfully used to produce high mechanical quality factor and optomechanical coupling which enabled the observation of cooling and amplification of mechanical modes at low temperature.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {mastersthesis}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('228','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_228\" style=\"display:none;\"><div class=\"tp_abstract_entry\">The field of cavity optomechanics has experienced a rapid growth in last decade. The increasing interest in this area was mostly driven by the intricate interface between mechanical motion and the optical field. Such coupling is widely explored in a variety of experiments scaling from kilometer long interferometers to micrometer optical cavities. The challenge on all these experiments is to create an optomechanical device with long-living optical and mechanical resonances while keeping a large coupling rate. In this context photonic crystal cavities have emerged as a strong candidate since they are able to produce very small optical mode volume and long optical lifetime. In the classical regime, these tiny devices, which can mechanically oscillate from frequencies ranging from couple MHz up to tens of GHz, allows for highly sensitive small forces, masses, displacements and acceleration detectors. They are also used to produce high quality optically driven mechanical oscillators which can be synchronized via an optical field. In the quantum regime, cavity quantum optomechanics is being used to understand decoherence phenomena in a mesoscopic scale by creating nonclassical states between light and mechanical modes intermediated by optomechanical interaction. However up to now, few studies have been done concerning the possibility of large scale production of these devices, a necessary step towards massive technological and scientific application of these devices. <br \/>\r\nIn this work, we describe a detailed study of optomechanical cavities based upon photonic crystal cavities fabricated in a CMOS-compatible commercial foundry. We prove the feasibil- ity of this platform exploring three photonic crystal designs. First, we show how to achieve ultra-high optical quality factors using a design resilient to the fabrication constrains. Our demonstrated quality factors are the largest ever reported using photonic crystal cavities man- ufactured by optical lithography. Secondly, we investigate a slot type optical cavity, able to produce very large optomechanical coupling using a simple in-plane motion. Finally, we design a trimmable acoustic shield to restrict the mechanical motion inside the optical region. Such strategy was successfully used to produce high mechanical quality factor and optomechanical coupling which enabled the observation of cooling and amplification of mechanical modes at low temperature.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('228','tp_abstract')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_2015\">2015<\/h3><h3 class=\"tp_h3\" id=\"tp_h3_article\">Journal Articles<\/h3><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, Mario C. M. M.;  Rezende, Guilherme F. M.;  Barea, Luis A. M.; von Zuben, Antonio A. G.;  Wiederhecker, Gustavo S.;  Frateschi, Newton C.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('143','tp_links')\" style=\"cursor:pointer;\">Spectral engineering with coupled microcavities: active control of resonant mode-splitting<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Opt. Lett., <\/span><span class=\"tp_pub_additional_volume\">vol. 40, <\/span><span class=\"tp_pub_additional_number\">no. 14, <\/span><span class=\"tp_pub_additional_pages\">pp. 3332\u20133335, <\/span><span class=\"tp_pub_additional_year\">2015<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_143\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('143','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_143\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('143','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_143\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('143','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_143\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Souza:15,<br \/>\r\ntitle = {Spectral engineering with coupled microcavities: active control of resonant mode-splitting},<br \/>\r\nauthor = {Mario C. M. M. Souza and Guilherme F. M. Rezende and Luis A. M. Barea and Antonio A. G. von Zuben and Gustavo S. Wiederhecker and Newton C. Frateschi},<br \/>\r\nurl = {http:\/\/ol.osa.org\/abstract.cfm?URI=ol-40-14-3332},<br \/>\r\ndoi = {10.1364\/OL.40.003332},<br \/>\r\nyear  = {2015},<br \/>\r\ndate = {2015-07-01},<br \/>\r\njournal = {Opt. Lett.},<br \/>\r\nvolume = {40},<br \/>\r\nnumber = {14},<br \/>\r\npages = {3332--3335},<br \/>\r\npublisher = {OSA},<br \/>\r\nabstract = {Optical mode-splitting is an efficient tool to shape and fine-tune the spectral response of resonant nanophotonic devices. The active control of mode-splitting, however, is either small or accompanied by undesired resonance-shifts, often much larger than the resonance splitting. We report a control mechanism that enables reconfigurable and widely tunable mode splitting while efficiently mitigating undesired resonance shifts. This is achieved by actively controlling the excitation of counter-traveling modes in coupled resonators. The transition from a large splitting (80&#xA0;GHz) to a single-notch resonance is demonstrated using low-power microheaters (35&#xA0;mW). We show that the spurious resonance shift in our device is only limited by thermal crosstalk, and resonance-shift-free splitting control may be achieved.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('143','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_143\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Optical mode-splitting is an efficient tool to shape and fine-tune the spectral response of resonant nanophotonic devices. The active control of mode-splitting, however, is either small or accompanied by undesired resonance-shifts, often much larger than the resonance splitting. We report a control mechanism that enables reconfigurable and widely tunable mode splitting while efficiently mitigating undesired resonance shifts. This is achieved by actively controlling the excitation of counter-traveling modes in coupled resonators. The transition from a large splitting (80&amp;#xA0;GHz) to a single-notch resonance is demonstrated using low-power microheaters (35&amp;#xA0;mW). We show that the spurious resonance shift in our device is only limited by thermal crosstalk, and resonance-shift-free splitting control may be achieved.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('143','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_143\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/ol.osa.org\/abstract.cfm?URI=ol-40-14-3332\" title=\"http:\/\/ol.osa.org\/abstract.cfm?URI=ol-40-14-3332\" target=\"_blank\">http:\/\/ol.osa.org\/abstract.cfm?URI=ol-40-14-3332<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OL.40.003332\" title=\"Follow DOI:10.1364\/OL.40.003332\" target=\"_blank\">doi:10.1364\/OL.40.003332<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('143','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_inproceedings\">Proceedings Articles<\/h3><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, Mario C.;  Barea, Luis A.;  Wiederhecker, Gustavo; von Zuben, Antonio A.;  Frateschi, Newton C.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('146','tp_links')\" style=\"cursor:pointer;\">Tunable Spectral Engineering of Coupled Silicon Microcavities<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">CLEO: 2015, <\/span><span class=\"tp_pub_additional_pages\">pp. JTu5A.49, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2015<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_146\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('146','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_146\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('146','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_146\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('146','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_146\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Souza:2015aa,<br \/>\r\ntitle = {Tunable Spectral Engineering of Coupled Silicon Microcavities},<br \/>\r\nauthor = {Mario C. Souza and Luis A. Barea and Gustavo Wiederhecker and Antonio A. von Zuben and Newton C. Frateschi},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2015-JTu5A.49},<br \/>\r\nyear  = {2015},<br \/>\r\ndate = {2015-01-01},<br \/>\r\nbooktitle = {CLEO: 2015},<br \/>\r\njournal = {CLEO: 2015},<br \/>\r\npages = {JTu5A.49},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {We demonstrate the generation and control of optical resonance mode-splitting arising from a single-notch resonances using coupled silicon microring resonators with electrically controlled counter-propagating mode excitation.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('146','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_146\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate the generation and control of optical resonance mode-splitting arising from a single-notch resonances using coupled silicon microring resonators with electrically controlled counter-propagating mode excitation.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('146','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_146\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2015-JTu5A.49\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2015-JTu5A.49\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=CLEO_QELS-2015-JTu5A.49<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('146','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Benevides, Rodrigo;  Luiz, Gustavo O.;  Santos, Felipe G.;  Wiederhecker, Gustavo S.;  Alegre, Thiago<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('145','tp_links')\" style=\"cursor:pointer;\">Optomechanical Crystals Fabricated by a CMOS Foundry<\/a> <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">Frontiers in Optics 2015, <\/span><span class=\"tp_pub_additional_pages\">pp. FTu5C.3, <\/span><span class=\"tp_pub_additional_publisher\">Optical Society of America, <\/span><span class=\"tp_pub_additional_year\">2015<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_145\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('145','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_145\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('145','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_145\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('145','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_145\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{Benevides:15,<br \/>\r\ntitle = {Optomechanical Crystals Fabricated by a CMOS Foundry},<br \/>\r\nauthor = {Rodrigo Benevides and Gustavo O. Luiz and Felipe G. Santos and Gustavo S. Wiederhecker and Thiago Alegre},<br \/>\r\nurl = {http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2015-FTu5C.3},<br \/>\r\ndoi = {10.1364\/FIO.2015.FTu5C.3},<br \/>\r\nyear  = {2015},<br \/>\r\ndate = {2015-01-01},<br \/>\r\nbooktitle = {Frontiers in Optics 2015},<br \/>\r\njournal = {Frontiers in Optics 2015},<br \/>\r\npages = {FTu5C.3},<br \/>\r\npublisher = {Optical Society of America},<br \/>\r\nabstract = {Photonics crystal optomechanical cavities fabricated on a commercial CMOS-compatible foundry are demonstrated. Despite the limited foundry design rules we could achieve a ultra-high Q (9.1texttimes105) photonic crystals and optomechanical crystal cavities with large coupling rate (g 0$=$60 KHz).},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('145','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_145\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Photonics crystal optomechanical cavities fabricated on a commercial CMOS-compatible foundry are demonstrated. Despite the limited foundry design rules we could achieve a ultra-high Q (9.1texttimes105) photonic crystals and optomechanical crystal cavities with large coupling rate (g 0$=$60 KHz).<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('145','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_145\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2015-FTu5C.3\" title=\"http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2015-FTu5C.3\" target=\"_blank\">http:\/\/www.osapublishing.org\/abstract.cfm?URI=FiO-2015-FTu5C.3<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/FIO.2015.FTu5C.3\" title=\"Follow DOI:10.1364\/FIO.2015.FTu5C.3\" target=\"_blank\">doi:10.1364\/FIO.2015.FTu5C.3<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('145','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Barea, Luis A; von Zuben, Antonio A;  M-Brahim, Tayeb;  Montagnoli, Arlindo N;  Hospital, Michel;  Frateschi, N;  Cirino, Giuseppe A<\/p><p class=\"tp_pub_title\">Fresnel Zone Plate Array Fabricated by Maskless Lithography <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">2015 30TH SYMPOSIUM ON MICROELECTRONICS TECHNOLOGY AND DEVICES (SBMICRO), <\/span><span class=\"tp_pub_additional_organization\">Univ Fed Bahia; PET Engn Electrica; Sociedade Brasileira Computacao; \r\n Sociedade Brasileira Microelectronica; IEEE Solid State Circuits Soc; \r\n IEEE Elect Devices Soc; IFIP; CAPES; CNPq; SENAI CIMATEC <\/span><span class=\"tp_pub_additional_publisher\">IEEE, <\/span><span class=\"tp_pub_additional_address\">345 E 47TH ST, NEW YORK, NY 10017 USA, <\/span><span class=\"tp_pub_additional_year\">2015<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-4673-7162-9<\/span><span class=\"tp_pub_additional_note\">, (30th Symposium on Microelectronics Technology and Devices (SBMicro), \r\n Salvador, BRAZIL, AUG 31-SEP 04, 2015)<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_222\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('222','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_222\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('222','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_222\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{ISI:000378423000052,<br \/>\r\ntitle = {Fresnel Zone Plate Array Fabricated by Maskless Lithography},<br \/>\r\nauthor = {Luis A Barea and Antonio A von Zuben and Tayeb M-Brahim and Arlindo N Montagnoli and Michel Hospital and N Frateschi and Giuseppe A Cirino},<br \/>\r\nisbn = {978-1-4673-7162-9},<br \/>\r\nyear  = {2015},<br \/>\r\ndate = {2015-01-01},<br \/>\r\nbooktitle = {2015 30TH SYMPOSIUM ON MICROELECTRONICS TECHNOLOGY AND DEVICES (SBMICRO)},<br \/>\r\npublisher = {IEEE},<br \/>\r\naddress = {345 E 47TH ST, NEW YORK, NY 10017 USA},<br \/>\r\norganization = {Univ Fed Bahia; PET Engn Electrica; Sociedade Brasileira Computacao; <br \/>\r\n Sociedade Brasileira Microelectronica; IEEE Solid State Circuits Soc; <br \/>\r\n IEEE Elect Devices Soc; IFIP; CAPES; CNPq; SENAI CIMATEC},<br \/>\r\nabstract = {This work reports the fabrication of Fresnel Zone Plates (FZP) by <br \/>\r\n employing a maskless lithography tool based on direct laser writing. The <br \/>\r\n target application areas in this work are to use a micro lens array <br \/>\r\n (MLA) in a wavefront sensor, for optical aberrations quantification in <br \/>\r\n human eye diagnostics or adaptive optical system. This last one is <br \/>\r\n essential in astronomy applications in order to correct the aberrations <br \/>\r\n introduced by earth atmosphere. The fabricated FZP generates <br \/>\r\n illumination points with high contrast intensity in the focal plane, <br \/>\r\n which is the purpose of the wavefront sensor. This high-contrast image <br \/>\r\n suggests that the employed fabrication process is well controlled and it <br \/>\r\n matches the design parameters.},<br \/>\r\nnote = {30th Symposium on Microelectronics Technology and Devices (SBMicro), <br \/>\r\n Salvador, BRAZIL, AUG 31-SEP 04, 2015},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('222','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_222\" style=\"display:none;\"><div class=\"tp_abstract_entry\">This work reports the fabrication of Fresnel Zone Plates (FZP) by <br \/>\r\n employing a maskless lithography tool based on direct laser writing. The <br \/>\r\n target application areas in this work are to use a micro lens array <br \/>\r\n (MLA) in a wavefront sensor, for optical aberrations quantification in <br \/>\r\n human eye diagnostics or adaptive optical system. This last one is <br \/>\r\n essential in astronomy applications in order to correct the aberrations <br \/>\r\n introduced by earth atmosphere. The fabricated FZP generates <br \/>\r\n illumination points with high contrast intensity in the focal plane, <br \/>\r\n which is the purpose of the wavefront sensor. This high-contrast image <br \/>\r\n suggests that the employed fabrication process is well controlled and it <br \/>\r\n matches the design parameters.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('222','tp_abstract')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\">de Rezende, Guilherme F M;  Souza, Mario C M M;  Frateschi, Newton C<\/p><p class=\"tp_pub_title\">Limitations of Coupled Mode Theory to Model Coupled Microresonators \r\n ``Dark States'' <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">2015 30TH SYMPOSIUM ON MICROELECTRONICS TECHNOLOGY AND DEVICES (SBMICRO), <\/span><span class=\"tp_pub_additional_organization\">Univ Fed Bahia; PET Engn Electrica; Sociedade Brasileira Computacao; \r\n Sociedade Brasileira Microelectronica; IEEE Solid State Circuits Soc; \r\n IEEE Elect Devices Soc; IFIP; CAPES; CNPq; SENAI CIMATEC <\/span><span class=\"tp_pub_additional_publisher\">IEEE, <\/span><span class=\"tp_pub_additional_address\">345 E 47TH ST, NEW YORK, NY 10017 USA, <\/span><span class=\"tp_pub_additional_year\">2015<\/span>, <span class=\"tp_pub_additional_isbn\">ISBN: 978-1-4673-7162-9<\/span><span class=\"tp_pub_additional_note\">, (30th Symposium on Microelectronics Technology and Devices (SBMicro), \r\n Salvador, BRAZIL, AUG 31-SEP 04, 2015)<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_223\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('223','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_223\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('223','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_223\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{ISI:000378423000024,<br \/>\r\ntitle = {Limitations of Coupled Mode Theory to Model Coupled Microresonators <br \/>\r\n ``Dark States''},<br \/>\r\nauthor = {Guilherme F M de Rezende and Mario C M M Souza and Newton C Frateschi},<br \/>\r\nisbn = {978-1-4673-7162-9},<br \/>\r\nyear  = {2015},<br \/>\r\ndate = {2015-01-01},<br \/>\r\nbooktitle = {2015 30TH SYMPOSIUM ON MICROELECTRONICS TECHNOLOGY AND DEVICES (SBMICRO)},<br \/>\r\npublisher = {IEEE},<br \/>\r\naddress = {345 E 47TH ST, NEW YORK, NY 10017 USA},<br \/>\r\norganization = {Univ Fed Bahia; PET Engn Electrica; Sociedade Brasileira Computacao; <br \/>\r\n Sociedade Brasileira Microelectronica; IEEE Solid State Circuits Soc; <br \/>\r\n IEEE Elect Devices Soc; IFIP; CAPES; CNPq; SENAI CIMATEC},<br \/>\r\nabstract = {In this work we present analytical and experimental results indicating <br \/>\r\n that Coupled Mode Theory, unlike the Transfer Matrix Method, may have <br \/>\r\n limitations in predicting the behavior of photonic molecules based on <br \/>\r\n embedded coupled microring cavities. We show that this resonant <br \/>\r\n mode-based approach fails to provide the correct transmission spectrum <br \/>\r\n for some important coupled cavity configurations, although correctly <br \/>\r\n predicting the existence of these modes as eigenstates of the coupled <br \/>\r\n system. The measured transmission spectrum of a CMOS compatible tunable <br \/>\r\n photonic molecule is used to demonstrate this limitation.},<br \/>\r\nnote = {30th Symposium on Microelectronics Technology and Devices (SBMicro), <br \/>\r\n Salvador, BRAZIL, AUG 31-SEP 04, 2015},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('223','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_223\" style=\"display:none;\"><div class=\"tp_abstract_entry\">In this work we present analytical and experimental results indicating <br \/>\r\n that Coupled Mode Theory, unlike the Transfer Matrix Method, may have <br \/>\r\n limitations in predicting the behavior of photonic molecules based on <br \/>\r\n embedded coupled microring cavities. We show that this resonant <br \/>\r\n mode-based approach fails to provide the correct transmission spectrum <br \/>\r\n for some important coupled cavity configurations, although correctly <br \/>\r\n predicting the existence of these modes as eigenstates of the coupled <br \/>\r\n system. The measured transmission spectrum of a CMOS compatible tunable <br \/>\r\n photonic molecule is used to demonstrate this limitation.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('223','tp_abstract')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_inproceedings\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, Mario C M M;  Barea, Luis A M; von Zuben, Antonio A G;  Wiederhecker, Gustavo S;  Frateschi, Newton C<\/p><p class=\"tp_pub_title\">Tunable Spectral Engineering of Coupled Silicon Microcavities <span class=\"tp_pub_type tp_  inproceedings\">Proceedings Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_booktitle\">2015 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO), <\/span><span class=\"tp_pub_additional_publisher\">IEEE, <\/span><span class=\"tp_pub_additional_address\">345 E 47TH ST, NEW YORK, NY 10017 USA, <\/span><span class=\"tp_pub_additional_year\">2015<\/span>, <span class=\"tp_pub_additional_issn\">ISSN: 2160-9020<\/span><span class=\"tp_pub_additional_note\">, (Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, MAY 10-15, \r\n 2015)<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_218\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('218','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_218\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('218','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_218\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@inproceedings{ISI:000370627101190,<br \/>\r\ntitle = {Tunable Spectral Engineering of Coupled Silicon Microcavities},<br \/>\r\nauthor = {Mario C M M Souza and Luis A M Barea and Antonio A G von Zuben and Gustavo S Wiederhecker and Newton C Frateschi},<br \/>\r\nissn = {2160-9020},<br \/>\r\nyear  = {2015},<br \/>\r\ndate = {2015-01-01},<br \/>\r\nbooktitle = {2015 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO)},<br \/>\r\npublisher = {IEEE},<br \/>\r\naddress = {345 E 47TH ST, NEW YORK, NY 10017 USA},<br \/>\r\nseries = {Conference on Lasers and Electro-Optics},<br \/>\r\nabstract = {We demonstrate the generation and control of optical resonance <br \/>\r\n mode-splitting arising from a single-notch resonance using coupled <br \/>\r\n silicon microring resonators with electrically controlled <br \/>\r\n counter-propagating mode excitation. (C) 2014 Optical Society of America},<br \/>\r\nnote = {Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, MAY 10-15, <br \/>\r\n 2015},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {inproceedings}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('218','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_218\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We demonstrate the generation and control of optical resonance <br \/>\r\n mode-splitting arising from a single-notch resonance using coupled <br \/>\r\n silicon microring resonators with electrically controlled <br \/>\r\n counter-propagating mode excitation. (C) 2014 Optical Society of America<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('218','tp_abstract')\">Close<\/a><\/p><\/div><\/div><\/div><h3 class=\"tp_h3\" id=\"tp_h3_2014\">2014<\/h3><h3 class=\"tp_h3\" id=\"tp_h3_article\">Journal Articles<\/h3><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Souza, M. C. M. M.;  Barea, L. A. M.;  Vallini, F.;  Rezende, G. F. M.;  Wiederhecker, G. S.;  Frateschi, N. C.<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('154','tp_links')\" style=\"cursor:pointer;\">Embedded coupled microrings with high-finesse and close-spaced resonances for optical signal processing<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Optics Express, <\/span><span class=\"tp_pub_additional_volume\">vol. 22, <\/span><span class=\"tp_pub_additional_number\">no. 9, <\/span><span class=\"tp_pub_additional_pages\">pp. 10430-10438, <\/span><span class=\"tp_pub_additional_year\">2014<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_154\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('154','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_154\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('154','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_154\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('154','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_154\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Souza201410430,<br \/>\r\ntitle = {Embedded coupled microrings with high-finesse and close-spaced resonances for optical signal processing},<br \/>\r\nauthor = {Souza, M.C.M.M. and Barea, L.A.M. and Vallini, F. and Rezende, G.F.M. and Wiederhecker, G.S. and Frateschi, N.C.},<br \/>\r\nurl = {http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84899854737&amp;partnerID=40&amp;md5=7e75faaeebcfccc28776dcf2cc3635d9},<br \/>\r\ndoi = {10.1364\/OE.22.010430},<br \/>\r\nyear  = {2014},<br \/>\r\ndate = {2014-01-01},<br \/>\r\njournal = {Optics Express},<br \/>\r\nvolume = {22},<br \/>\r\nnumber = {9},<br \/>\r\npages = {10430-10438},<br \/>\r\nabstract = {Single microring resonators have been used in applications such as wavelength multicasting and microwave photonics, but the dependence of the free spectral range with ring radius imposes a trade-off between the required GHz optical channel spacing, footprint and power consumption. We demonstrate four-channel all-optical wavelength multicasting using only 1 mW of control power, with converted channel spacing of 40-60 GHz. Our device is based on a compact embedded microring design fabricated on a scalable SOI platform. The coexistence of close resonance spacing and high finesse (205) in a compact footprint is possible due to enhanced quality factors (30,000) resulting from the embedded configuration and the coupling-strength dependence of resonance spacing, instead of ring size. In addition, we discuss the possibility of achieving continuously mode splitting from a single-notch resonance up to 40 GHz. copyright 2014 Optical Society of America.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('154','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_154\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Single microring resonators have been used in applications such as wavelength multicasting and microwave photonics, but the dependence of the free spectral range with ring radius imposes a trade-off between the required GHz optical channel spacing, footprint and power consumption. We demonstrate four-channel all-optical wavelength multicasting using only 1 mW of control power, with converted channel spacing of 40-60 GHz. Our device is based on a compact embedded microring design fabricated on a scalable SOI platform. The coexistence of close resonance spacing and high finesse (205) in a compact footprint is possible due to enhanced quality factors (30,000) resulting from the embedded configuration and the coupling-strength dependence of resonance spacing, instead of ring size. In addition, we discuss the possibility of achieving continuously mode splitting from a single-notch resonance up to 40 GHz. copyright 2014 Optical Society of America.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('154','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_154\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84899854737&amp;amp;partnerID=40&amp;amp;md5=7e75faaeebcfccc28776dcf2cc3635d9\" title=\"http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84899854737&amp;amp;partnerID[...]\" target=\"_blank\">http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84899854737&amp;amp;partnerID[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1364\/OE.22.010430\" title=\"Follow DOI:10.1364\/OE.22.010430\" target=\"_blank\">doi:10.1364\/OE.22.010430<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('154','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Gu, Q. a;  Shane, J. a;  Vallini, F. b;  Wingad, B. a;  Smalley, J. S. T. a;  Frateschi, N. C. b;  Fainman, Y. a<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('157','tp_links')\" style=\"cursor:pointer;\">Amorphous Al2O3 shield for thermal management in electrically pumped metallo-dielectric nanolasers<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">IEEE Journal of Quantum Electronics, <\/span><span class=\"tp_pub_additional_volume\">vol. 50, <\/span><span class=\"tp_pub_additional_number\">no. 7, <\/span><span class=\"tp_pub_additional_pages\">pp. 499-509, <\/span><span class=\"tp_pub_additional_year\">2014<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_157\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('157','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_157\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('157','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_157\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('157','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_157\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Gu2014499,<br \/>\r\ntitle = {Amorphous Al2O3 shield for thermal management in electrically pumped metallo-dielectric nanolasers},<br \/>\r\nauthor = {Gu, Q.a and Shane, J.a and Vallini, F.b and Wingad, B.a and Smalley, J.S.T.a and Frateschi, N.C.b and Fainman, Y.a},<br \/>\r\nurl = {http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84901332397&amp;partnerID=40&amp;md5=60c6d9b35f5a951fecb6ca959ac73556},<br \/>\r\ndoi = {10.1109\/JQE.2014.2321746},<br \/>\r\nyear  = {2014},<br \/>\r\ndate = {2014-01-01},<br \/>\r\njournal = {IEEE Journal of Quantum Electronics},<br \/>\r\nvolume = {50},<br \/>\r\nnumber = {7},<br \/>\r\npages = {499-509},<br \/>\r\nabstract = {We analyze amorphous Al2O3 (\u03b1-Al 2O3) for use as a thick thermally conductive shield in metallo-dielectric semiconductor nanolasers, and show that the use of (alpha ) -Al2O3 allows a laser to efficiently dissipate heat through its shield. This new mechanism for thermal management leads to a significantly lower operating temperature within the laser, compared with lasers with less thermally conductive shields, such as SiO2. We implement the shield in a continuous wave electrically pumped cavity, and analyze its experimental performance by jointly investigating its optical, electrical, thermal, and material gain properties. Our analysis shows that the primary obstacle to room temperature lasing was the device's high threshold gain. At the high pump levels required to achieve the gain threshold, particularly at room temperature, the gain spectrum broadened and shifted, leading to detrimental mode competition. Further simulations predict that an increase in the pedestal undercut depth should enable room temperature lasing in a device with the same footprint and gain volume. Through the integrated treatment of various physical effects, this analysis shows the promise of (\u03b1-Al2O3 for nanolaser thermal management, and enables better understanding of nanolaser behavior, as well as more informed design of reliable nanolasers. copyright 2014 IEEE.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('157','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_157\" style=\"display:none;\"><div class=\"tp_abstract_entry\">We analyze amorphous Al2O3 (\u03b1-Al 2O3) for use as a thick thermally conductive shield in metallo-dielectric semiconductor nanolasers, and show that the use of (alpha ) -Al2O3 allows a laser to efficiently dissipate heat through its shield. This new mechanism for thermal management leads to a significantly lower operating temperature within the laser, compared with lasers with less thermally conductive shields, such as SiO2. We implement the shield in a continuous wave electrically pumped cavity, and analyze its experimental performance by jointly investigating its optical, electrical, thermal, and material gain properties. Our analysis shows that the primary obstacle to room temperature lasing was the device's high threshold gain. At the high pump levels required to achieve the gain threshold, particularly at room temperature, the gain spectrum broadened and shifted, leading to detrimental mode competition. Further simulations predict that an increase in the pedestal undercut depth should enable room temperature lasing in a device with the same footprint and gain volume. Through the integrated treatment of various physical effects, this analysis shows the promise of (\u03b1-Al2O3 for nanolaser thermal management, and enables better understanding of nanolaser behavior, as well as more informed design of reliable nanolasers. copyright 2014 IEEE.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('157','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_157\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84901332397&amp;amp;partnerID=40&amp;amp;md5=60c6d9b35f5a951fecb6ca959ac73556\" title=\"http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84901332397&amp;amp;partnerID[...]\" target=\"_blank\">http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84901332397&amp;amp;partnerID[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1109\/JQE.2014.2321746\" title=\"Follow DOI:10.1109\/JQE.2014.2321746\" target=\"_blank\">doi:10.1109\/JQE.2014.2321746<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('157','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><div class=\"tp_publication tp_publication_article\"><div class=\"tp_pub_info\"><p class=\"tp_pub_author\"> Zhang, M. a;  Luiz, G. b;  Shah, S. a;  Wiederhecker, G. b;  Lipson, M. a c<\/p><p class=\"tp_pub_title\"><a class=\"tp_title_link\" onclick=\"teachpress_pub_showhide('159','tp_links')\" style=\"cursor:pointer;\">Eliminating anchor loss in optomechanical resonators using elastic wave interference<\/a> <span class=\"tp_pub_type tp_  article\">Journal Article<\/span> <\/p><p class=\"tp_pub_additional\"><span class=\"tp_pub_additional_in\">In: <\/span><span class=\"tp_pub_additional_journal\">Applied Physics Letters, <\/span><span class=\"tp_pub_additional_volume\">vol. 105, <\/span><span class=\"tp_pub_additional_number\">no. 5, <\/span><span class=\"tp_pub_additional_year\">2014<\/span>.<\/p><p class=\"tp_pub_menu\"><span class=\"tp_abstract_link\"><a id=\"tp_abstract_sh_159\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('159','tp_abstract')\" title=\"Show abstract\" style=\"cursor:pointer;\">Abstract<\/a><\/span> | <span class=\"tp_resource_link\"><a id=\"tp_links_sh_159\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('159','tp_links')\" title=\"Show links and resources\" style=\"cursor:pointer;\">Links<\/a><\/span> | <span class=\"tp_bibtex_link\"><a id=\"tp_bibtex_sh_159\" class=\"tp_show\" onclick=\"teachpress_pub_showhide('159','tp_bibtex')\" title=\"Show BibTeX entry\" style=\"cursor:pointer;\">BibTeX<\/a><\/span><\/p><div class=\"tp_bibtex\" id=\"tp_bibtex_159\" style=\"display:none;\"><div class=\"tp_bibtex_entry\"><pre>@article{Zhang2014,<br \/>\r\ntitle = {Eliminating anchor loss in optomechanical resonators using elastic wave interference},<br \/>\r\nauthor = {Zhang, M.a and Luiz, G.b and Shah, S.a and Wiederhecker, G.b and Lipson, M.a c},<br \/>\r\nurl = {http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84905671257&amp;partnerID=40&amp;md5=548b8970d7257673a286f6684b0406c3},<br \/>\r\ndoi = {10.1063\/1.4892417},<br \/>\r\nyear  = {2014},<br \/>\r\ndate = {2014-01-01},<br \/>\r\njournal = {Applied Physics Letters},<br \/>\r\nvolume = {105},<br \/>\r\nnumber = {5},<br \/>\r\nabstract = {Optomechanical resonators suffer from the dissipation of mechanical energy through the necessary anchors enabling the suspension of the structure. Here, we show that such structural loss in an optomechanical oscillator can be almost completely eliminated through the destructive interference of elastic waves using dual-disk structures. We also present both analytical and numerical models that predict the observed interference of elastic waves. Our experimental data reveal unstressed silicon nitride (Si3N4) devices with mechanical Q-factors up to 104 at mechanical frequencies of f=102 MHz (fQ=1012) at room temperature. copyright 2014 AIP Publishing LLC.},<br \/>\r\nkeywords = {},<br \/>\r\npubstate = {published},<br \/>\r\ntppubtype = {article}<br \/>\r\n}<br \/>\r\n<\/pre><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('159','tp_bibtex')\">Close<\/a><\/p><\/div><div class=\"tp_abstract\" id=\"tp_abstract_159\" style=\"display:none;\"><div class=\"tp_abstract_entry\">Optomechanical resonators suffer from the dissipation of mechanical energy through the necessary anchors enabling the suspension of the structure. Here, we show that such structural loss in an optomechanical oscillator can be almost completely eliminated through the destructive interference of elastic waves using dual-disk structures. We also present both analytical and numerical models that predict the observed interference of elastic waves. Our experimental data reveal unstressed silicon nitride (Si3N4) devices with mechanical Q-factors up to 104 at mechanical frequencies of f=102 MHz (fQ=1012) at room temperature. copyright 2014 AIP Publishing LLC.<\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('159','tp_abstract')\">Close<\/a><\/p><\/div><div class=\"tp_links\" id=\"tp_links_159\" style=\"display:none;\"><div class=\"tp_links_entry\"><ul class=\"tp_pub_list\"><li><i class=\"fas fa-globe\"><\/i><a class=\"tp_pub_list\" href=\"http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84905671257&amp;amp;partnerID=40&amp;amp;md5=548b8970d7257673a286f6684b0406c3\" title=\"http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84905671257&amp;amp;partnerID[...]\" target=\"_blank\">http:\/\/www.scopus.com\/inward\/record.url?eid=2-s2.0-84905671257&amp;amp;partnerID[...]<\/a><\/li><li><i class=\"ai ai-doi\"><\/i><a class=\"tp_pub_list\" href=\"https:\/\/dx.doi.org\/10.1063\/1.4892417\" title=\"Follow DOI:10.1063\/1.4892417\" target=\"_blank\">doi:10.1063\/1.4892417<\/a><\/li><\/ul><\/div><p class=\"tp_close_menu\"><a class=\"tp_close\" onclick=\"teachpress_pub_showhide('159','tp_links')\">Close<\/a><\/p><\/div><\/div><\/div><\/div><\/div>\n<p><strong>Copyright Notices<\/strong><\/p>\n<p style=\"text-align: justify\"><span style=\"font-size: 8pt\"><strong>AIP:<\/strong> Copyright\u00a9 (2006-2011) American Institute of Physics. This article may be downloaded for personal use only. Any other use requires prior permission of the author and the American Institute of Physics. <strong>APS:<\/strong> The right, after publication by APS, to use all or part of the Article without revision or modification, including the APS-formatted version, in print compilations or other print publications of the author(s)\u2019 and\/or the employer\u2019s own works, and on the author(s)\u2019 and\/or the employer\u2019s web home page, and to make copies of all or part of the Article for the author(s)\u2019 and\/or the employer\u2019s use for lecture or classroom purposes. <strong>OSA:<\/strong> The right, after publication by OSA, to use all or part of the Work without revision or modification, including the OSA-formatted version, in personal compilations or other publications consisting solely of the Author(s\u2019) own works, including the Author(s\u2019) personal web home page, and to make copies of all or part of the Work for the Author(s\u2019) use for lecture or classroom purposes.<\/span><\/p>\n<p><\/p>","protected":false},"excerpt":{"rendered":"<p>Copyright Notices AIP: Copyright\u00a9 (2006-2011) American Institute of Physics. 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