Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2023 |
| Outros Autores: | , , , |
| Tipo de documento: | Artigo |
| Idioma: | eng |
| Título da fonte: | The Journal of Engineering and Exact Sciences |
| Texto Completo: | https://periodicos.ufv.br/jcec/article/view/17804 |
Resumo: | The exponential growth in publications and applications of perovskite photovoltaic cells highlights their significance in energy conversion and carbon emissions mitigation. From 2009 to 2023, the efficiency of these cells has significantly increased from 3.9% to 25.7%. The adaptive capacity of perovskite structures for solar spectrum absorption and current displacement is strongly influenced by the bandgap energy, ideally situated between 1.3 and 1.7 eV. Although various perovskite compositions can potentially attain this energy range, the synthesis methodologies remain empirically driven, presenting challenges to experimental viability. In this context, leveraging experimental databases provided by global researchers emerges as an effective approach to expedite and enable research on perovskite structures for photovoltaic cells. This study utilized the comprehensive MaterialsZone database to feed machine learning algorithms, focusing on Support Vector Machine (SVM) and Random Forest (RF) methodologies to predict the bandgap energy in a targeted perovskite composition. By conducting synthesis experiments towards specific compositions guided by model predictions, it becomes feasible to efficiently achieve the desired bandgap energy. Such a strategy not only accelerates research progress but also serves to curtail costs associated with the synthesis of perovskite materials. The RF model exhibited an average percentage error of 5.13%, a standard deviation of the percentage error of 6.99%, and a Root Mean Square Error (RMSE) of 0.119. In contrast, the SVM model recorded an average percentage error of 4.05%, a standard deviation of the percentage error of 6.45%, and RMSE of 0.881. These developed models not only demonstrate high predictive capacity but also contribute substantively to the comprehension of the intricate relationship between the chemical composition and bandgap energy values of perovskites. By deploying machine learning algorithms, this work paves the way for targeted optimizations and considerable strides in the manufacturing of perovskite-based photovoltaic cells. |
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Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine LearningCélula solar de perovskita: composição química e energia de bandgap via aprendizado de máquinaPerovskitePhotovoltaic cellsBandgapSupport Vector Machines (SVM)Random Forest (RF)Floresta Aleatória (RF)PerovskitaCélulas fotovoltaicasBandgapMáquinas de Vetores de Suporte (SVM)The exponential growth in publications and applications of perovskite photovoltaic cells highlights their significance in energy conversion and carbon emissions mitigation. From 2009 to 2023, the efficiency of these cells has significantly increased from 3.9% to 25.7%. The adaptive capacity of perovskite structures for solar spectrum absorption and current displacement is strongly influenced by the bandgap energy, ideally situated between 1.3 and 1.7 eV. Although various perovskite compositions can potentially attain this energy range, the synthesis methodologies remain empirically driven, presenting challenges to experimental viability. In this context, leveraging experimental databases provided by global researchers emerges as an effective approach to expedite and enable research on perovskite structures for photovoltaic cells. This study utilized the comprehensive MaterialsZone database to feed machine learning algorithms, focusing on Support Vector Machine (SVM) and Random Forest (RF) methodologies to predict the bandgap energy in a targeted perovskite composition. By conducting synthesis experiments towards specific compositions guided by model predictions, it becomes feasible to efficiently achieve the desired bandgap energy. Such a strategy not only accelerates research progress but also serves to curtail costs associated with the synthesis of perovskite materials. The RF model exhibited an average percentage error of 5.13%, a standard deviation of the percentage error of 6.99%, and a Root Mean Square Error (RMSE) of 0.119. In contrast, the SVM model recorded an average percentage error of 4.05%, a standard deviation of the percentage error of 6.45%, and RMSE of 0.881. These developed models not only demonstrate high predictive capacity but also contribute substantively to the comprehension of the intricate relationship between the chemical composition and bandgap energy values of perovskites. By deploying machine learning algorithms, this work paves the way for targeted optimizations and considerable strides in the manufacturing of perovskite-based photovoltaic cells.O crescimento exponencial nas publicações e aplicações das células fotovoltaicas de perovskita destaca sua relevância na conversão de energia e na mitigação das emissões de carbono. No período de 2009 a 2023, a eficiência dessas células evoluiu significativamente, passando de 3,9% para 25,7%. A capacidade adaptativa das estruturas perovskitas para a absorção do espectro solar e o deslocamento de corrente é fortemente influenciada pela energia da banda de gap, idealmente situada entre 1,3 e 1,7 eV. Embora diversas composições de perovskita possam atingir essa faixa de energia, as sínteses continuam sendo empíricas, apresentando desafios para a viabilidade experimental. Nesse contexto, a utilização de bancos de dados experimentais, fornecidos por pesquisadores globais, emerge como uma abordagem eficaz para acelerar e viabilizar a pesquisa das estruturas perovskitas destinadas a células fotovoltaicas. Este estudo empregou o banco de dados da plataforma MaterialsZone para alimentar algoritmos de aprendizado de máquina, concentrando-se nas técnicas de Máquina de Vetores de Suporte (SVM) e Floresta Aleatória (RF) para a predição de energia da banda de gap em uma composição específica de perovskita. Ao direcionar os experimentos de síntese para composições particulares, orientadas pelas predições dos modelos, é possível alcançar a energia da banda de gap desejada de maneira eficiente. Esse enfoque resulta em avanços mais rápidos na pesquisa, reduzindo os custos associados à síntese de perovskitas. O modelo RF apresentou um erro percentual médio de 5,13%, desvio padrão do erro percentual de 6,99%, e Erro Quadrático Médio (RMSE) de 0,119. Por outro lado, o SVM registrou um erro percentual médio de 4,05%, desvio padrão do erro percentual de 6,45%, e RMSE de 0,881. Os modelos desenvolvidos não apenas demonstram uma alta capacidade preditiva, mas também fundamentam o entendimento da relação entre a composição química e os valores de energia da banda de gap das perovskitas. Ao empregar algoritmos de aprendizado de máquina, este trabalho abre caminho para otimizações direcionadas, e ainda, impulsiona avanços substanciais na fabricação de células fotovoltaicas baseadas em perovskita.Universidade Federal de Viçosa - UFV2023-12-28info:eu-repo/semantics/articleinfo:eu-repo/semantics/publishedVersionapplication/pdfhttps://periodicos.ufv.br/jcec/article/view/1780410.18540/jcecvl9iss9pp17804The Journal of Engineering and Exact Sciences; Vol. 9 No. 9 (2023); 17804The Journal of Engineering and Exact Sciences; Vol. 9 Núm. 9 (2023); 17804The Journal of Engineering and Exact Sciences; v. 9 n. 9 (2023); 178042527-1075reponame:The Journal of Engineering and Exact Sciencesinstname:Universidade Federal de Viçosa (UFV)instacron:UFVenghttps://periodicos.ufv.br/jcec/article/view/17804/9113Copyright (c) 2023 The Journal of Engineering and Exact Scienceshttps://creativecommons.org/licenses/by/4.0info:eu-repo/semantics/openAccessSantos, Filipi França dosDa Silveira, Kelly CristineFerreira, Gesiane MendonçaCariello, Daniella HerdiAndrade, Mônica Calixto de2023-12-28T22:46:21Zoai:ojs.periodicos.ufv.br:article/17804Revistahttp://www.seer.ufv.br/seer/rbeq2/index.php/req2/oai2527-10752527-1075opendoar:2023-12-28T22:46:21The Journal of Engineering and Exact Sciences - Universidade Federal de Viçosa (UFV)false |
| dc.title.none.fl_str_mv |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning Célula solar de perovskita: composição química e energia de bandgap via aprendizado de máquina |
| title |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning |
| spellingShingle |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning Santos, Filipi França dos Perovskite Photovoltaic cells Bandgap Support Vector Machines (SVM) Random Forest (RF) Floresta Aleatória (RF) Perovskita Células fotovoltaicas Bandgap Máquinas de Vetores de Suporte (SVM) |
| title_short |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning |
| title_full |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning |
| title_fullStr |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning |
| title_full_unstemmed |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning |
| title_sort |
Perovskite Solar Cell: Chemical Composition and Bandgap Energy via Machine Learning |
| author |
Santos, Filipi França dos |
| author_facet |
Santos, Filipi França dos Da Silveira, Kelly Cristine Ferreira, Gesiane Mendonça Cariello, Daniella Herdi Andrade, Mônica Calixto de |
| author_role |
author |
| author2 |
Da Silveira, Kelly Cristine Ferreira, Gesiane Mendonça Cariello, Daniella Herdi Andrade, Mônica Calixto de |
| author2_role |
author author author author |
| dc.contributor.author.fl_str_mv |
Santos, Filipi França dos Da Silveira, Kelly Cristine Ferreira, Gesiane Mendonça Cariello, Daniella Herdi Andrade, Mônica Calixto de |
| dc.subject.por.fl_str_mv |
Perovskite Photovoltaic cells Bandgap Support Vector Machines (SVM) Random Forest (RF) Floresta Aleatória (RF) Perovskita Células fotovoltaicas Bandgap Máquinas de Vetores de Suporte (SVM) |
| topic |
Perovskite Photovoltaic cells Bandgap Support Vector Machines (SVM) Random Forest (RF) Floresta Aleatória (RF) Perovskita Células fotovoltaicas Bandgap Máquinas de Vetores de Suporte (SVM) |
| description |
The exponential growth in publications and applications of perovskite photovoltaic cells highlights their significance in energy conversion and carbon emissions mitigation. From 2009 to 2023, the efficiency of these cells has significantly increased from 3.9% to 25.7%. The adaptive capacity of perovskite structures for solar spectrum absorption and current displacement is strongly influenced by the bandgap energy, ideally situated between 1.3 and 1.7 eV. Although various perovskite compositions can potentially attain this energy range, the synthesis methodologies remain empirically driven, presenting challenges to experimental viability. In this context, leveraging experimental databases provided by global researchers emerges as an effective approach to expedite and enable research on perovskite structures for photovoltaic cells. This study utilized the comprehensive MaterialsZone database to feed machine learning algorithms, focusing on Support Vector Machine (SVM) and Random Forest (RF) methodologies to predict the bandgap energy in a targeted perovskite composition. By conducting synthesis experiments towards specific compositions guided by model predictions, it becomes feasible to efficiently achieve the desired bandgap energy. Such a strategy not only accelerates research progress but also serves to curtail costs associated with the synthesis of perovskite materials. The RF model exhibited an average percentage error of 5.13%, a standard deviation of the percentage error of 6.99%, and a Root Mean Square Error (RMSE) of 0.119. In contrast, the SVM model recorded an average percentage error of 4.05%, a standard deviation of the percentage error of 6.45%, and RMSE of 0.881. These developed models not only demonstrate high predictive capacity but also contribute substantively to the comprehension of the intricate relationship between the chemical composition and bandgap energy values of perovskites. By deploying machine learning algorithms, this work paves the way for targeted optimizations and considerable strides in the manufacturing of perovskite-based photovoltaic cells. |
| publishDate |
2023 |
| dc.date.none.fl_str_mv |
2023-12-28 |
| dc.type.driver.fl_str_mv |
info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion |
| format |
article |
| status_str |
publishedVersion |
| dc.identifier.uri.fl_str_mv |
https://periodicos.ufv.br/jcec/article/view/17804 10.18540/jcecvl9iss9pp17804 |
| url |
https://periodicos.ufv.br/jcec/article/view/17804 |
| identifier_str_mv |
10.18540/jcecvl9iss9pp17804 |
| dc.language.iso.fl_str_mv |
eng |
| language |
eng |
| dc.relation.none.fl_str_mv |
https://periodicos.ufv.br/jcec/article/view/17804/9113 |
| dc.rights.driver.fl_str_mv |
Copyright (c) 2023 The Journal of Engineering and Exact Sciences https://creativecommons.org/licenses/by/4.0 info:eu-repo/semantics/openAccess |
| rights_invalid_str_mv |
Copyright (c) 2023 The Journal of Engineering and Exact Sciences https://creativecommons.org/licenses/by/4.0 |
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openAccess |
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application/pdf |
| dc.publisher.none.fl_str_mv |
Universidade Federal de Viçosa - UFV |
| publisher.none.fl_str_mv |
Universidade Federal de Viçosa - UFV |
| dc.source.none.fl_str_mv |
The Journal of Engineering and Exact Sciences; Vol. 9 No. 9 (2023); 17804 The Journal of Engineering and Exact Sciences; Vol. 9 Núm. 9 (2023); 17804 The Journal of Engineering and Exact Sciences; v. 9 n. 9 (2023); 17804 2527-1075 reponame:The Journal of Engineering and Exact Sciences instname:Universidade Federal de Viçosa (UFV) instacron:UFV |
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Universidade Federal de Viçosa (UFV) |
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UFV |
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UFV |
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The Journal of Engineering and Exact Sciences |
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The Journal of Engineering and Exact Sciences |
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The Journal of Engineering and Exact Sciences - Universidade Federal de Viçosa (UFV) |
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