Estudo da aplicação de nanofios de óxido de zinco modificados em sistema de fotoeletrocatálise heterogênea
| dc.contributor.advisor | Raphael, Ellen | |
| dc.contributor.advisor-lattes | http://lattes.cnpq.br/1077764607984864 | |
| dc.contributor.author | Brasil, Guilherme Bittencourt | |
| dc.contributor.author-lattes | http://lattes.cnpq.br/2680779870266253 | |
| dc.contributor.referee1 | Rocha, Siomara Dias da | |
| dc.contributor.referee2 | Moriya, Regina Yanako | |
| dc.date.accessioned | 2025-07-09T15:17:56Z | |
| dc.date.issued | 2025-07-10 | |
| dc.description.abstract | The Chemical industry’s growth forced a change of scenario for industrial wastewater treatment, on which the as-called persistent organic pollutants (POP’s), a series of chemically resistant, highly harmful and bioaccumulative substances, suddenly make up a significant fraction of the output flows from industrial processes, generating effluents with high chemical oxygen demand (COD) and incompatible with traditional treatment techniques. In this context, the so called advanced oxidative processes become an attractive alternative to reduce the content of these compounds to tolerable levels without inducing secondary pollution. In particular, photocatalytic processes are highly targeted for their ability to reduce high COD loads. The present work explores the application of carbon dots modified ZnO nanowires as a low-cost catalyst to act in a photoelectrocatalysis process, an improvement on traditional photocatalytic processes, aiming at the degradation of rhodamine B, a widely used industrial dye. The proposed objectives were to synthesize the nanomaterials that make up the catalyst composite in the laboratory, build a bench scale reactor to carry out batch photoelectrocatalysis tests and characterize the degradation kinetics of rhodamine B using the prepared photoanodes. The constructed reactor proved to be suitable for conducting kinetic tests on a bench scale and could be used in the future by students at the State University of Amazonas to carry out experiments focused on photoelectrochemistry. The photoelectrocatalytic treatment process proved to be significantly more effective than the photochemical and electrochemical oxidation processes under similar conditions, achieving a reduction of 95.7% of rhodamine B concentration in 250 mL of 1 mg.L-1 solution using a ZnO based photoanode. The kinetics of the reaction showed satisfactory compatibility with the pseudo first order model in relation to the concentration of rhodamine in solution, thus it was possible to determine the specific speed of the reaction catalyzed by the ZnO nanowires, finding a value of 0,048 ± 0.004 min-1 . The modification of the ZnO nanowire film with the addition of the synthesized carbon dots resulted in a notable reduction in its catalytic activity, reducing the degree of removal to 45,6% and the specific speed to 0,0058 ± 0,0005 min-1 , against the initial expectations. | |
| dc.description.resumo | A expansão da indústria química forçou uma mudança de paradigma no tratamento dos efluentes industriais, no qual os chamados poluentes orgânicos persistentes (POP’s) uma série de substâncias quimicamente resistentes, altamente nocivos e bioacumulativos passaram a compor uma fração significativa dos caudais de saída dos processos industriais, gerando efluentes com alta demanda química de oxigênio (DQO) e incompatíveis com as técnicas de tratamento tradicionais. Nesse contexto os chamados processos oxidativos avançados tornam-se uma alternativa atraente para reduzir o teor desses compostos a níveis toleráveis sem ocasionar poluição secundária. Em especial, os processos fotocatalíticos são altamente visados pela sua capacidade de reduzir elevadas cargas de DQO. O presente trabalho explora aplicação de nanofios de ZnO modificados com pontos de carbono como catalisador de baixo custo para atuar em processo de fotoeletrocatálise, um aprimoramento dos processos fotocatalíticos tradicionais, visando a degradação de rodamina B, um corante industrial amplamente utilizado. Os objetivos propostos foram sintetizar os nanomateriais que compõem o compósito catalisador em laboratório, construir um reator em escala de bancada para realização dos testes de fotoeletrocatálise em regime batelada e caracterizar a cinética de degradação da rodamina B com o uso dos fotoanodos preparados. O reator construído se mostrou adequado para condução dos ensaios cinéticos em escala de bancada e poderá ser utilizado futuramente por alunos da Universidade do Estado do Amazonas para a realização de experimentos focados em fotoeletroquímica. O processo de tratamento fotoeletrocatalítico se mostrou significativamente mais eficaz que os processos de oxidação fotoquímica e eletroquímica em condições similares, alcançando uma redução de 95,7% da concentração de rodamina B em 250 mL de solução a 1 mg.L-1 utilizando fotoanodo a base de ZnO. A cinética da reação mostrou compatibilidade satisfatória com o modelo de pseudo-primeira ordem com relação à concentração de rodamina em solução, com isso foi possível determinar a velocidade específica da reação catalisada pelos nanofios de ZnO, encontrando-se o valor de 0,048 ± 0,004 min-1 . A modificação do filme de nanofios de ZnO com adição dos pontos de carbono sintetizados resultou em uma notável redução da sua atividade catalítica, reduzindo o grau de remoção para 45,6% e a velocidade específica para 0,0058 ± 0,0005 min-1 , contrariando as expectativas iniciais. | |
| dc.identifier.citation | Brasil, Guilherme Bittencourt. Estudo da aplicação de nanofios de óxido de zinco modificados em sistema de fotoeletrocatálise heterogênea. 2024. 1 CD ROM. TCC (Graduação em Engenharia Química) - Universidade do Estado do Amazonas, Manaus, 2024. | |
| dc.identifier.uri | https://ri.uea.edu.br/handle/riuea/7704 | |
| dc.language.iso | pt | |
| dc.publisher | Universidade do Estado do Amazonas | |
| dc.publisher.initials | UEA | |
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| dc.rights | Attribution-NonCommercial-NoDerivs 3.0 United States | en |
| dc.rights.uri | http://creativecommons.org/licenses/by-nc-nd/3.0/us/ | |
| dc.subject | Pontos de carbono | |
| dc.subject | Tratamento de efluentes | |
| dc.subject | Fotoeletrocatálise | |
| dc.subject | Estudo cinético | |
| dc.subject | Degradação de rodamina B | |
| dc.title | Estudo da aplicação de nanofios de óxido de zinco modificados em sistema de fotoeletrocatálise heterogênea | |
| dc.title.alternative | Study of the application of modified zinc oxide nanowires in heterogeneous photoelectrocatalysis systems | |
| dc.type | Trabalho de Conclusão de Curso |
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