Projeto e análise óptica de estruturas de filtro-absorvedor reconfiguráveis integradas com materiais de mudança de fase

Oliveira, Israel Alves

Campo DC

Valor

Idioma

dc.creator

Oliveira, Israel Alves

dc.date.accessioned

2026-02-25T19:18:35Z

dc.date.available

2026-02-13

dc.date.available

2026-02-25T19:18:35Z

dc.date.issued

2025-12-29

dc.identifier.uri

https://repositorio.ufba.br/handle/ri/44097

dc.description.abstract

Phase‐change materials (PCMs) based on chalcogenides have emerged as promising functional platforms due to their unique ability to combine state retention, an essential feature for non-volatile memory applications, with pronounced contrasts in electrical and optical properties between the amorphous and crystalline phases. Over the past decade, these materials have been extensively explored in optics and photonics, driven by their high refractive-index contrast, non-volatility, and compatibility with integration processes on established photonic platforms. This thesis presents the development, modeling, and analysis of reconfigurable photonic devices based on PCMs. The proposed work investigates the use of GeTe, In3SbTe2 (IST), and Sb2S3 in active and tunable optical applications, taking advantage of their distinctive optical properties that enable dynamic spectral modulation through reversible phase transitions. Such transitions allow active control over the absorption, reflection, and transmission of electromagnetic radiation. The developed architectures include planar and multilayer nanoscale configurations, with emphasis on ultrathin optical absorbers and filters. The analyses were performed through numerical simulations based on the Finite Element Method (FEM), incorporating realistic, wavelength-dependent dispersive models. For Sb2S3 in particular, experimental studies were also carried out, involving the nanofabrication of thin films via physical vapor deposition (PVD) and spectroscopic ellipsometry characterization conducted at École Centrale de Lyon (France). From these measurements, complex optical parameters were extracted for both phase states, showing excellent agreement with the simulated results, thereby validating both the developed optical model and the suitability of Sb2S3 for actively controlled photonic devices. The results demonstrate the strong potential of PCMs for enabling reconfigurable photonic architectures aimed at spectral modulation, optical sensing, and communication applications. The proposed devices were designed to operate from the visible to the mid-infrared spectral ranges, exploiting different physical mechanisms associated with electromagnetic field interaction and confinement, including resonance effects, interference, and optical coupling. Finally, the influences of geometric and material parameters on device performance are analyzed, along with the feasibility of nanoscale fabrication. These findings highlight the relevance of PCMs for next-generation integrated photonics and programmable optoelectronic technologies.

pt_BR

dc.description.sponsorship

CAPES

pt_BR

dc.language

eng

pt_BR

dc.publisher

UNIVERSIDADE FEDERAL DA BAHIA

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dc.rights

Acesso Aberto

pt_BR

dc.subject

Materiais com mudança de fase

pt_BR

dc.subject

Método dos Elementos Finitos

pt_BR

dc.subject

Dispositivos nanofotônicos

pt_BR

dc.subject

Absorvedores sintonizáveis e filtros

pt_BR

dc.subject

Caracterização

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dc.subject

Nanofabricação de filmes finos

pt_BR

dc.subject.other

Phase-change materials

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dc.subject.other

Finite Element Method (FEM)

pt_BR

dc.subject.other

Nanophotonic devices

pt_BR

dc.subject.other

Tunable absorbers and filters

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dc.subject.other

Optical characterization

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dc.subject.other

Thin-film nanofabrication

pt_BR

dc.title

Projeto e análise óptica de estruturas de filtro-absorvedor reconfiguráveis integradas com materiais de mudança de fase

pt_BR

dc.title.alternative

Design and optical analysis of reconfigurable filter-absorbers structures integrated with phase change materials

pt_BR

dc.type

Tese

pt_BR

dc.contributor.referees

Rubio Mercedes, Cosme Eustaquio

dc.contributor.referees

Rego, Davi Franco

dc.publisher.program

Programa de Pós-Graduação em Engenharia Elétrica (PPGEE)

pt_BR

dc.publisher.initials

UFBA

pt_BR

dc.publisher.country

Brasil

pt_BR

dc.subject.cnpq

CNPQ::ENGENHARIAS

pt_BR

dc.contributor.advisor1

Rodriguez-Esquerre, Vitaly Felix

dc.contributor.advisor1Lattes

http://lattes.cnpq.br/9324813375750858

pt_BR

dc.contributor.advisor-co1

Souza, Igor Leonardo Gomes de

dc.contributor.advisor-co1Lattes

http://lattes.cnpq.br/7568755699926541

pt_BR

dc.contributor.referee1

Rodriguez-Esquerre, Vitaly Felix

dc.contributor.referee1Lattes

http://lattes.cnpq.br/9324813375750858

pt_BR

dc.contributor.referee2

Souza, Igor Leonardo Gomes de

dc.contributor.referee2Lattes

http://lattes.cnpq.br/7568755699926541

pt_BR

dc.contributor.referee3

Hernandez Figueroa, Hugo Enrique

dc.contributor.referee3Lattes

http://lattes.cnpq.br/4870907540258696

pt_BR

dc.contributor.referee4

Alayo Chavez, Marco Isaías

dc.contributor.referee4Lattes

http://lattes.cnpq.br/7881987532843700

pt_BR

dc.contributor.referee5

Pohl, Alexandre de Almeida Prado

dc.contributor.referee5Lattes

http://lattes.cnpq.br/9118815178885363

pt_BR

dc.creator.Lattes

http://lattes.cnpq.br/7671815710338395

pt_BR

dc.description.resumo

Materiais de mudança de fase (PCMs) à base de calcogenetos têm se destacado como plataformas funcionais promissoras devido à sua capacidade de combinar retenção de estado (característica essencial para aplicações em memória não volátil) com elevados contrastes nas propriedades elétricas e ópticas entre as fases amorfa e cristalina. Ao longo da última década, esses materiais têm sido amplamente investigados no campo da óptica e da fotônica, impulsionados por seu alto contraste de índice de refração, comportamento não volátil e compatibilidade com processos de integração em plataformas fotônicas consolidadas. Esta tese apresenta o desenvolvimento, a modelagem e a análise de dispositivos fotônicos reconfiguráveis baseados em PCMs. A proposta explora o uso de GeTe, In3SbTe2 (IST) e Sb2S3 em aplicações de óptica ativa e sintonizável, tirando proveito das propriedades ópticas peculiares desses materiais, que permitem modulação espectral dinâmica por meio de transições reversíveis entre os estados amorfo e cristalino. Tais transições possibilitam controlar, de forma ativa, a absorção e transmissão da radiação eletromagnética em diferentes regiões do espectro. As arquiteturas desenvolvidas incluem configurações planares e multicamadas em escala nanométrica, com ênfase em absorvedores e filtros ópticos. As análises foram conduzidas por meio de simulações numéricas baseadas no Método dos Elementos Finitos (FEM), incorporando modelos dispersivos realistas e dependentes do comprimento de onda. Para o caso específico do Sb2S3, também foram realizados estudos experimentais envolvendo a nanofabricação de filmes finos por deposição física a vapor (PVD) e caracterização óptica por elipsometria espectroscópica, conduzidos na École Centrale de Lyon (França). A partir dessas medições, foi possível extrair parâmetros ópticos complexos em ambas as fases do material, apresentando excelente concordância com os resultados obtidos numericamente, o que valida tanto o modelo desenvolvido quanto a aplicabilidade do Sb2S3 em dispositivos fotônicos de controle ativo. Os resultados demonstram o grande potencial dos PCMs na concepção de dispositivos fotônicos reconfiguráveis destinados à modulação espectral, sensoriamento óptico e aplicações em comunicações. Os dispositivos propostos foram projetados para operar desde a região visível até o infravermelho médio, explorando diferentes mecanismos físicos associados à interação e ao confinamento do campo eletromagnético, incluindo efeitos de ressonância, interferência e acoplamento óptico. Por fim, são discutidos os impactos dos parâmetros geométricos e das propriedades materiais sobre o desempenho das estruturas, bem como a viabilidade de fabricação em escala nanométrica, destacando o potencial desses dispositivos para aplicações em fotônica integrada e tecnologias optoeletrônicas programáveis.

pt_BR

dc.publisher.department

Escola Politécnica

pt_BR

dc.relation.references

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