Impacto da adição de grafeno nos compostos intermetálicos (IMC) e propriedades mecânicas da liga Sn-Bi submetidas à ciclagem térmica

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dc.contributor.advisorMacêdo Neto, José Costa de
dc.contributor.advisor-latteshttps://lattes.cnpq.br/7868540287547126
dc.contributor.authorPádua, Gabriel Fabricio Rocha de Carvalho
dc.contributor.author-latteshttps://lattes.cnpq.br/4695460410635276
dc.contributor.referee1Macêdo Neto, José Costa de
dc.contributor.referee1Latteshttps://lattes.cnpq.br/7868540287547126
dc.contributor.referee2Bello, Roger Hoel
dc.contributor.referee2Latteshttps://lattes.cnpq.br/0479686945106210
dc.contributor.referee3Mesquita, Antônio de Lima
dc.contributor.referee3Latteshttps://lattes.cnpq.br/7920404121091345
dc.date.accessioned2026-03-20T16:40:56Z
dc.date.issued2026-03-31
dc.description.abstractThe addition of graphene nanosheets (GNSs) to Sn–Bi alloys has been explored to increase the performance and reliability of solder joints under severe thermal conditions. In this study, Sn-Bi–xGNSs alloys ranging from 0.0 to 0.5% by weight were prepared and applied to copper substrates, subjected to remelting and thermal cycling. The microstructures and intermetallic layers (IMCs) were evaluated by optical microscopy and microsection, and the mechanical properties by nanoindentation. All alloys composed of GNSs in the microstructure after remelting had refinement of the primary β-Sn phase in relation to the pure alloy of 0.0%, while after thermal cycling with 0.05% had the best refinement condition of the β-Sn phase, while contents >0.03% resulted in agglomeration of GNSs and loss of efficiency. After remelting and thermal cycling, the sample with 0.05% by weight showed a reduction of more than 40% and 34% in the thickness of the IMC layer, respectively. In the post-remelting sample with 0.1%, there was a 16% increase in the modulus of elasticity and, after thermal cycling, a 50% increase in the modulus of elasticity. The research highlights the influence of GNSs on microstructural refinement, control of IMC growth, and mechanical stability under thermal cycling.
dc.description.resumoA adição de nanofolhas de grafeno (GNSs) em ligas Sn–Bi tem sido explorada para aumentar o desempenho e confiabilidade de juntas de solda sob condições térmicas severas. Neste estudo, ligas Sn-Bi–xGNSs variando de 0,0 à 0,5% em peso foram preparadas e aplicadas sobre substratos de cobre, submetidas a processo de refusão e ciclos térmicos. As microestruturas e camadas intermetálicas (IMCs) foram avaliadas por microscopia óptica e microsection, e as propriedades mecânicas, por nanoindentação. Todas as ligas compostas de GNSs na microestrutura após refusão tiveram refinamento da fase β-Sn primária em relação a liga pura de 0,0%, já após ciclagem térmica com 0,05% teve a melhor condição de refinamento da fase β-Sn, enquanto teores >0,03% resultaram em aglomeração de GNSs e perda de eficiência. Após refusão e ciclagem térmica, a amostra com 0,05% em peso apresentou redução superior a 40% e 34% na espessura da camada de IMC respectivamente. Na amostra pós refusão com 0,1% teve aumento de 16% no módulo de elasticidade e após ciclagem térmica com 50% de aumento no módulo de elasticidade. A pesquisa destaca a influência do GNSs no refinamento microestrutural, controle do crescimento de IMCs e estabilidade mecânica sob ciclagem térmica.
dc.identifier.citationPÁDUA, Gabriel Fabricio Rocha de Carvalho. Impacto da adição de grafeno nos compostos intermetálicos (IMC) e propriedades mecânicas da liga Sn-Bi submetidas à ciclagem térmica. Manaus, 2025. 36f. TCC- (Graduação em Engenharia de Materiais) –Universidade do Estado do Amazonas. Escola Superior de Tecnologia.
dc.identifier.urihttps://ri.uea.edu.br/handle/riuea/8078
dc.publisherUniversidade do Estado do Amazonas
dc.publisher.initialsUEA
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dc.rightsAttribution-NonCommercial-NoDerivs 3.0 United Statesen
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/3.0/us/
dc.subjectGrafeno
dc.subjectLigas Sn-Bi
dc.subjectCompostos Intermetálicos
dc.subjectMicroestrutura
dc.subjectCiclagem Térmica
dc.titleImpacto da adição de grafeno nos compostos intermetálicos (IMC) e propriedades mecânicas da liga Sn-Bi submetidas à ciclagem térmica
dc.title.alternativeEffect of graphene addition on intermetallic compounds (IMCs) and the mechanical properties of Sn-Bi alloys subjected to thermal cycling
dc.typeTrabalho de Conclusão de Curso

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