Caroline R. Kwawu, Albert Aniagyei, Destiny Konadu, Boniface Yeboah Antwi
{"title":"Fe(100)上CO2还原成CO和甲酸的机理:DFT研究","authors":"Caroline R. Kwawu, Albert Aniagyei, Destiny Konadu, Boniface Yeboah Antwi","doi":"10.1007/s40243-021-00194-w","DOIUrl":null,"url":null,"abstract":"<p>Understanding the mechanism of CO<sub>2</sub> reduction on iron is crucial for the design of more efficient and cheaper iron electrocatalyst for CO<sub>2</sub> conversion. In the present study, we have employed spin-polarized density functional theory calculations within the generalized gradient approximation (DFT-GGA) to elucidate the mechanism of CO<sub>2</sub> reduction into carbon monoxide and formic acid on the Fe (100) facet. We also sort to understand the transformations of the other isomers of adsorbed CO<sub>2</sub> on iron as earlier mechanistic studies are centred on the transformations of the C<sub>2v</sub> geometry alone and not the other possible conformations i.e., flip-C<sub>2v</sub> and Cs modes. Two alternative reduction routes were considered i.e., the direct CO<sub>2</sub> dissociation against the hydrogen-assisted CO<sub>2</sub> transformation through formate and carboxylate into CO and formic acid. Our results show that CO<sub>2</sub> in the C<sub>2v</sub> mode is the precursor to the formation of both products i.e., CO and formic acid. Both the formation and transformation of CO<sub>2</sub> in the Cs and flip-C<sub>2v</sub> is challenging kinetically and thermodynamically compared to the C<sub>2v</sub> mode. The formic acid formation is favoured over CO via the reverse water gas shift reaction mechanism on Fe (100). Both formic acid formation and CO formation will proceed via the carboxylate intermediate since formate is a stable intermediate whose transformation into formic acid is challenging both kinetically and thermodynamically.</p>","PeriodicalId":692,"journal":{"name":"Materials for Renewable and Sustainable Energy","volume":"10 2","pages":""},"PeriodicalIF":3.6000,"publicationDate":"2021-04-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1007/s40243-021-00194-w","citationCount":"4","resultStr":"{\"title\":\"Mechanisms of CO2 reduction into CO and formic acid on Fe (100): a DFT study\",\"authors\":\"Caroline R. Kwawu, Albert Aniagyei, Destiny Konadu, Boniface Yeboah Antwi\",\"doi\":\"10.1007/s40243-021-00194-w\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Understanding the mechanism of CO<sub>2</sub> reduction on iron is crucial for the design of more efficient and cheaper iron electrocatalyst for CO<sub>2</sub> conversion. In the present study, we have employed spin-polarized density functional theory calculations within the generalized gradient approximation (DFT-GGA) to elucidate the mechanism of CO<sub>2</sub> reduction into carbon monoxide and formic acid on the Fe (100) facet. We also sort to understand the transformations of the other isomers of adsorbed CO<sub>2</sub> on iron as earlier mechanistic studies are centred on the transformations of the C<sub>2v</sub> geometry alone and not the other possible conformations i.e., flip-C<sub>2v</sub> and Cs modes. Two alternative reduction routes were considered i.e., the direct CO<sub>2</sub> dissociation against the hydrogen-assisted CO<sub>2</sub> transformation through formate and carboxylate into CO and formic acid. Our results show that CO<sub>2</sub> in the C<sub>2v</sub> mode is the precursor to the formation of both products i.e., CO and formic acid. Both the formation and transformation of CO<sub>2</sub> in the Cs and flip-C<sub>2v</sub> is challenging kinetically and thermodynamically compared to the C<sub>2v</sub> mode. The formic acid formation is favoured over CO via the reverse water gas shift reaction mechanism on Fe (100). 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Mechanisms of CO2 reduction into CO and formic acid on Fe (100): a DFT study
Understanding the mechanism of CO2 reduction on iron is crucial for the design of more efficient and cheaper iron electrocatalyst for CO2 conversion. In the present study, we have employed spin-polarized density functional theory calculations within the generalized gradient approximation (DFT-GGA) to elucidate the mechanism of CO2 reduction into carbon monoxide and formic acid on the Fe (100) facet. We also sort to understand the transformations of the other isomers of adsorbed CO2 on iron as earlier mechanistic studies are centred on the transformations of the C2v geometry alone and not the other possible conformations i.e., flip-C2v and Cs modes. Two alternative reduction routes were considered i.e., the direct CO2 dissociation against the hydrogen-assisted CO2 transformation through formate and carboxylate into CO and formic acid. Our results show that CO2 in the C2v mode is the precursor to the formation of both products i.e., CO and formic acid. Both the formation and transformation of CO2 in the Cs and flip-C2v is challenging kinetically and thermodynamically compared to the C2v mode. The formic acid formation is favoured over CO via the reverse water gas shift reaction mechanism on Fe (100). Both formic acid formation and CO formation will proceed via the carboxylate intermediate since formate is a stable intermediate whose transformation into formic acid is challenging both kinetically and thermodynamically.
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Energy is the single most valuable resource for human activity and the basis for all human progress. Materials play a key role in enabling technologies that can offer promising solutions to achieve renewable and sustainable energy pathways for the future.
Materials for Renewable and Sustainable Energy has been established to be the world''s foremost interdisciplinary forum for publication of research on all aspects of the study of materials for the deployment of renewable and sustainable energy technologies. The journal covers experimental and theoretical aspects of materials and prototype devices for sustainable energy conversion, storage, and saving, together with materials needed for renewable fuel production. It publishes reviews, original research articles, rapid communications, and perspectives. All manuscripts are peer-reviewed for scientific quality.
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