Plasmonic properties of metallic nanoparticle layers
| Ano de defesa: | 2019 |
|---|---|
| Autor(a) principal: | |
| Orientador(a): | |
| Banca de defesa: | |
| Tipo de documento: | Tese |
| Tipo de acesso: | Acesso aberto |
| Idioma: | eng |
| Instituição de defesa: |
Não Informado pela instituição
|
| Programa de Pós-Graduação: |
Não Informado pela instituição
|
| Departamento: |
Não Informado pela instituição
|
| País: |
Não Informado pela instituição
|
| Palavras-chave em Português: | |
| Link de acesso: | http://www.repositorio.ufc.br/handle/riufc/48274 |
Resumo: | Agglomerates of metallic nanoparticles (NPs) are known for a long time to interact remarkably with light, which leads them to a wide range of applications, from high-resolution imaging to solar cells. The self-assembly technique has drawn attention lately as it allows the synthesis of very close-packed nanoparticle clusters with high parameters precision and relatively low cost. This thesis provides a thorough theoretical investigation of the optical properties of mono-, bi- and few-layers made of gold and silver nanoparticles, showing also crucial experimental results that solidly support the study. Finite-difference time-domain (FDTD) simulations predict the excitation of one bright plasmon mode at the monolayers and two plasmon modes at the bilayers, one bright and one dark mode, identified by the parallel and antiparallel induced dipoles between the layers, respectively. A plane linearly polarized incident wave with propagation normal to the film is used. The dark mode excitation is allowed by field retardation that becomes dominant when the size of the nanoparticles is sufficiently large. The spectral properties of the mode, such as resonance energy and linewidth, can be tuned by changing the nanoparticles sizes and their separation. The simulations predict also a high density of nearfield hotspots with intensity enhancement of up to 3000, which indicates that these materials are excellent for spectroscopy applications. Microabsorbance measurements on gold bi- and trilayers show the characteristic absorbance peak from the dark interlayer modes, confirming the simulation predictions. For other few-layers with higher layer numbers, new dark plasmon modes are excited and a standing wave behavior starts to emerge, in which most of the light gets passed through the material and is no longer absorbed. We investigate the possibility of employing the layers for hot-electron generation, providing both FDTD simulations and time-resolved transient absorption experiments. Furthermore, we observe that placing the layers onto a reflective surface leads to a tremendous increase in the optical absorption of the dark modes. All methods we used are very reproducible and the simulated results can be verified experimentally with a relatively simple setup. This study opens the way for many new explorations in both fundamental and applied research. |
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Vieira, Bruno Gondim de MeloBarros, Eduardo Bedê2019-12-09T17:28:29Z2019-12-09T17:28:29Z2019VIEIRA, B. G. M. Plasmonic properties of metallic nanoparticle layers. 78 f. Tese (Doutorado em Física) - Universidade Federal do Ceará, Fortaleza, 2019.http://www.repositorio.ufc.br/handle/riufc/48274Agglomerates of metallic nanoparticles (NPs) are known for a long time to interact remarkably with light, which leads them to a wide range of applications, from high-resolution imaging to solar cells. The self-assembly technique has drawn attention lately as it allows the synthesis of very close-packed nanoparticle clusters with high parameters precision and relatively low cost. This thesis provides a thorough theoretical investigation of the optical properties of mono-, bi- and few-layers made of gold and silver nanoparticles, showing also crucial experimental results that solidly support the study. Finite-difference time-domain (FDTD) simulations predict the excitation of one bright plasmon mode at the monolayers and two plasmon modes at the bilayers, one bright and one dark mode, identified by the parallel and antiparallel induced dipoles between the layers, respectively. A plane linearly polarized incident wave with propagation normal to the film is used. The dark mode excitation is allowed by field retardation that becomes dominant when the size of the nanoparticles is sufficiently large. The spectral properties of the mode, such as resonance energy and linewidth, can be tuned by changing the nanoparticles sizes and their separation. The simulations predict also a high density of nearfield hotspots with intensity enhancement of up to 3000, which indicates that these materials are excellent for spectroscopy applications. Microabsorbance measurements on gold bi- and trilayers show the characteristic absorbance peak from the dark interlayer modes, confirming the simulation predictions. For other few-layers with higher layer numbers, new dark plasmon modes are excited and a standing wave behavior starts to emerge, in which most of the light gets passed through the material and is no longer absorbed. We investigate the possibility of employing the layers for hot-electron generation, providing both FDTD simulations and time-resolved transient absorption experiments. Furthermore, we observe that placing the layers onto a reflective surface leads to a tremendous increase in the optical absorption of the dark modes. All methods we used are very reproducible and the simulated results can be verified experimentally with a relatively simple setup. This study opens the way for many new explorations in both fundamental and applied research.Os aglomerados de nanopartículas (NPs) metálicas são conhecidos há muito tempo por sua notável interação com a luz, o que os leva a uma vasta gama de aplicações, desde imagens de alta resolução até células solares. A técnica de automontagem (self-assembly) tem chamado atenção ultimamente, já que ela permite a síntese de aglomerados de nanopartículas altamente compactados com alta precisão de parâmetros e custo relativamente baixo. Esta tese fornece uma investigação teórica aprofundada das propriedades ópticas de mono-, bi- e poucas camadas feitas de nanopartículas de ouro e prata, em que se mostra também resultados experimentais cruciais ao embasamento sólido do estudo. Simulações com o método de diferenças finitas no domínio do tempo (FDTD) preveem a excitação de um modo de plasmon claro nas monocamadas e dois modos de plasmon nas bicamadas, um claro e um escuro, identificados pelos dipolos induzidos paralela e antiparalelamente entre as camadas, respectivamente. Nos cálculos, utilizou-se uma onda incidente linearmente polarizada com propagação normal ao filme. A excitação do modo escuro é permitida pelo efeito de retardo de campo, que se torna dominante quando o tamanho das nanopartículas é suficientemente grande. As propriedades espectrais do modo, tais como energia de ressonância e largura de linha, podem ser ajustadas alterando-se os tamanhos das nanopartículas e sua separação. As simulações preveem também uma alta densidade de hotspots com aumento de intensidade de campo próximo de até 3000, o que indica que esses materiais são excelentes para aplicações em espectroscopia. As medições de microabsorbância em bi- e tricamadas de ouro mostram o pico de absorbância característico dos modos escuros, confirmando as previsões da simulação. Para estruturas com um maior número de camadas, novos modos de plasmon escuros são excitados e um comportamento de onda estacionária começa a emergir, que faz com que a maior parte da luz passe pelo material e não seja mais absorvida. Investigou-se também a possibilidade de empregar esses materiais na geração de elétrons quentes (hot-electrons), em que se apresenta simulações de FDTD e experimentos de absorção transiente resolvidos no tempo. Além disso, observamos que a deposição das camadas em uma superfície refletora leva a um tremendo aumento na absorção óptica dos modos escuros. Vale ressaltar que todos os métodos utilizados são reprodutíveis e os resultados simulados podem ser verificados experimentalmente com uma aparelhagem relativamente simples. Esse estudo abre caminho para muitas novas explorações, tanto em pesquisa fundamental quanto em aplicada.NanopartículasPlasmonDiferenças finitas no domínio do tempo (FDTD);Plasmonic properties of metallic nanoparticle layersPlasmonic properties of metallic nanoparticle layersinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/doctoralThesisengreponame:Repositório Institucional da Universidade Federal do Ceará (UFC)instname:Universidade Federal do Ceará (UFC)instacron:UFCinfo:eu-repo/semantics/openAccessORIGINAL2019_tese_bgmvieira.pdf2019_tese_bgmvieira.pdfapplication/pdf13774431http://repositorio.ufc.br/bitstream/riufc/48274/1/2019_tese_bgmvieira.pdfcfbe0b36de5af93cd3cb8d4a3a0fb42eMD51LICENSElicense.txtlicense.txttext/plain; charset=utf-81748http://repositorio.ufc.br/bitstream/riufc/48274/2/license.txt8a4605be74aa9ea9d79846c1fba20a33MD52riufc/482742020-10-22 19:00:57.381oai:repositorio.ufc.br:riufc/48274Tk9URTogUExBQ0UgWU9VUiBPV04gTElDRU5TRSBIRVJFClRoaXMgc2FtcGxlIGxpY2Vuc2UgaXMgcHJvdmlkZWQgZm9yIGluZm9ybWF0aW9uYWwgcHVycG9zZXMgb25seS4KCk5PTi1FWENMVVNJVkUgRElTVFJJQlVUSU9OIExJQ0VOU0UKCkJ5IHNpZ25pbmcgYW5kIHN1Ym1pdHRpbmcgdGhpcyBsaWNlbnNlLCB5b3UgKHRoZSBhdXRob3Iocykgb3IgY29weXJpZ2h0Cm93bmVyKSBncmFudHMgdG8gRFNwYWNlIFVuaXZlcnNpdHkgKERTVSkgdGhlIG5vbi1leGNsdXNpdmUgcmlnaHQgdG8gcmVwcm9kdWNlLAp0cmFuc2xhdGUgKGFzIGRlZmluZWQgYmVsb3cpLCBhbmQvb3IgZGlzdHJpYnV0ZSB5b3VyIHN1Ym1pc3Npb24gKGluY2x1ZGluZwp0aGUgYWJzdHJhY3QpIHdvcmxkd2lkZSBpbiBwcmludCBhbmQgZWxlY3Ryb25pYyBmb3JtYXQgYW5kIGluIGFueSBtZWRpdW0sCmluY2x1ZGluZyBidXQgbm90IGxpbWl0ZWQgdG8gYXVkaW8gb3IgdmlkZW8uCgpZb3UgYWdyZWUgdGhhdCBEU1UgbWF5LCB3aXRob3V0IGNoYW5naW5nIHRoZSBjb250ZW50LCB0cmFuc2xhdGUgdGhlCnN1Ym1pc3Npb24gdG8gYW55IG1lZGl1bSBvciBmb3JtYXQgZm9yIHRoZSBwdXJwb3NlIG9mIHByZXNlcnZhdGlvbi4KCllvdSBhbHNvIGFncmVlIHRoYXQgRFNVIG1heSBrZWVwIG1vcmUgdGhhbiBvbmUgY29weSBvZiB0aGlzIHN1Ym1pc3Npb24gZm9yCnB1cnBvc2VzIG9mIHNlY3VyaXR5LCBiYWNrLXVwIGFuZCBwcmVzZXJ2YXRpb24uCgpZb3UgcmVwcmVzZW50IHRoYXQgdGhlIHN1Ym1pc3Npb24gaXMgeW91ciBvcmlnaW5hbCB3b3JrLCBhbmQgdGhhdCB5b3UgaGF2ZQp0aGUgcmlnaHQgdG8gZ3JhbnQgdGhlIHJpZ2h0cyBjb250YWluZWQgaW4gdGhpcyBsaWNlbnNlLiBZb3UgYWxzbyByZXByZXNlbnQKdGhhdCB5b3VyIHN1Ym1pc3Npb24gZG9lcyBub3QsIHRvIHRoZSBiZXN0IG9mIHlvdXIga25vd2xlZGdlLCBpbmZyaW5nZSB1cG9uCmFueW9uZSdzIGNvcHlyaWdodC4KCklmIHRoZSBzdWJtaXNzaW9uIGNvbnRhaW5zIG1hdGVyaWFsIGZvciB3aGljaCB5b3UgZG8gbm90IGhvbGQgY29weXJpZ2h0LAp5b3UgcmVwcmVzZW50IHRoYXQgeW91IGhhdmUgb2J0YWluZWQgdGhlIHVucmVzdHJpY3RlZCBwZXJtaXNzaW9uIG9mIHRoZQpjb3B5cmlnaHQgb3duZXIgdG8gZ3JhbnQgRFNVIHRoZSByaWdodHMgcmVxdWlyZWQgYnkgdGhpcyBsaWNlbnNlLCBhbmQgdGhhdApzdWNoIHRoaXJkLXBhcnR5IG93bmVkIG1hdGVyaWFsIGlzIGNsZWFybHkgaWRlbnRpZmllZCBhbmQgYWNrbm93bGVkZ2VkCndpdGhpbiB0aGUgdGV4dCBvciBjb250ZW50IG9mIHRoZSBzdWJtaXNzaW9uLgoKSUYgVEhFIFNVQk1JU1NJT04gSVMgQkFTRUQgVVBPTiBXT1JLIFRIQVQgSEFTIEJFRU4gU1BPTlNPUkVEIE9SIFNVUFBPUlRFRApCWSBBTiBBR0VOQ1kgT1IgT1JHQU5JWkFUSU9OIE9USEVSIFRIQU4gRFNVLCBZT1UgUkVQUkVTRU5UIFRIQVQgWU9VIEhBVkUKRlVMRklMTEVEIEFOWSBSSUdIVCBPRiBSRVZJRVcgT1IgT1RIRVIgT0JMSUdBVElPTlMgUkVRVUlSRUQgQlkgU1VDSApDT05UUkFDVCBPUiBBR1JFRU1FTlQuCgpEU1Ugd2lsbCBjbGVhcmx5IGlkZW50aWZ5IHlvdXIgbmFtZShzKSBhcyB0aGUgYXV0aG9yKHMpIG9yIG93bmVyKHMpIG9mIHRoZQpzdWJtaXNzaW9uLCBhbmQgd2lsbCBub3QgbWFrZSBhbnkgYWx0ZXJhdGlvbiwgb3RoZXIgdGhhbiBhcyBhbGxvd2VkIGJ5IHRoaXMKbGljZW5zZSwgdG8geW91ciBzdWJtaXNzaW9uLgo=Repositório InstitucionalPUBhttp://www.repositorio.ufc.br/ri-oai/requestbu@ufc.br || repositorio@ufc.bropendoar:2020-10-22T22:00:57Repositório Institucional da Universidade Federal do Ceará (UFC) - Universidade Federal do Ceará (UFC)false |
| dc.title.pt_BR.fl_str_mv |
Plasmonic properties of metallic nanoparticle layers |
| dc.title.en.pt_BR.fl_str_mv |
Plasmonic properties of metallic nanoparticle layers |
| title |
Plasmonic properties of metallic nanoparticle layers |
| spellingShingle |
Plasmonic properties of metallic nanoparticle layers Vieira, Bruno Gondim de Melo Nanopartículas Plasmon Diferenças finitas no domínio do tempo (FDTD); |
| title_short |
Plasmonic properties of metallic nanoparticle layers |
| title_full |
Plasmonic properties of metallic nanoparticle layers |
| title_fullStr |
Plasmonic properties of metallic nanoparticle layers |
| title_full_unstemmed |
Plasmonic properties of metallic nanoparticle layers |
| title_sort |
Plasmonic properties of metallic nanoparticle layers |
| author |
Vieira, Bruno Gondim de Melo |
| author_facet |
Vieira, Bruno Gondim de Melo |
| author_role |
author |
| dc.contributor.author.fl_str_mv |
Vieira, Bruno Gondim de Melo |
| dc.contributor.advisor1.fl_str_mv |
Barros, Eduardo Bedê |
| contributor_str_mv |
Barros, Eduardo Bedê |
| dc.subject.por.fl_str_mv |
Nanopartículas Plasmon Diferenças finitas no domínio do tempo (FDTD); |
| topic |
Nanopartículas Plasmon Diferenças finitas no domínio do tempo (FDTD); |
| description |
Agglomerates of metallic nanoparticles (NPs) are known for a long time to interact remarkably with light, which leads them to a wide range of applications, from high-resolution imaging to solar cells. The self-assembly technique has drawn attention lately as it allows the synthesis of very close-packed nanoparticle clusters with high parameters precision and relatively low cost. This thesis provides a thorough theoretical investigation of the optical properties of mono-, bi- and few-layers made of gold and silver nanoparticles, showing also crucial experimental results that solidly support the study. Finite-difference time-domain (FDTD) simulations predict the excitation of one bright plasmon mode at the monolayers and two plasmon modes at the bilayers, one bright and one dark mode, identified by the parallel and antiparallel induced dipoles between the layers, respectively. A plane linearly polarized incident wave with propagation normal to the film is used. The dark mode excitation is allowed by field retardation that becomes dominant when the size of the nanoparticles is sufficiently large. The spectral properties of the mode, such as resonance energy and linewidth, can be tuned by changing the nanoparticles sizes and their separation. The simulations predict also a high density of nearfield hotspots with intensity enhancement of up to 3000, which indicates that these materials are excellent for spectroscopy applications. Microabsorbance measurements on gold bi- and trilayers show the characteristic absorbance peak from the dark interlayer modes, confirming the simulation predictions. For other few-layers with higher layer numbers, new dark plasmon modes are excited and a standing wave behavior starts to emerge, in which most of the light gets passed through the material and is no longer absorbed. We investigate the possibility of employing the layers for hot-electron generation, providing both FDTD simulations and time-resolved transient absorption experiments. Furthermore, we observe that placing the layers onto a reflective surface leads to a tremendous increase in the optical absorption of the dark modes. All methods we used are very reproducible and the simulated results can be verified experimentally with a relatively simple setup. This study opens the way for many new explorations in both fundamental and applied research. |
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2019 |
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2019-12-09T17:28:29Z |
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2019-12-09T17:28:29Z |
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2019 |
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info:eu-repo/semantics/publishedVersion |
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info:eu-repo/semantics/doctoralThesis |
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doctoralThesis |
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publishedVersion |
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VIEIRA, B. G. M. Plasmonic properties of metallic nanoparticle layers. 78 f. Tese (Doutorado em Física) - Universidade Federal do Ceará, Fortaleza, 2019. |
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http://www.repositorio.ufc.br/handle/riufc/48274 |
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VIEIRA, B. G. M. Plasmonic properties of metallic nanoparticle layers. 78 f. Tese (Doutorado em Física) - Universidade Federal do Ceará, Fortaleza, 2019. |
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http://www.repositorio.ufc.br/handle/riufc/48274 |
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eng |
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eng |
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