2D CoGeSe3 monolayer as a visible-light photocatalyst with high carrier mobility: Theoretical prediction

Abdul Jalil; Syed Zafar Ilyas; Simeon Agathopoulos; Ali Qureshi; Ishaq Ahmed; Tingkai Zhao

doi:10.1016/j.apsusc.2021.150588

2D CoGeSe₃ monolayer as a visible-light photocatalyst with high carrier mobility: Theoretical prediction

Abdul Jalil, Syed Zafar Ilyas, Simeon Agathopoulos, Ali Qureshi, Ishaq Ahmed, Tingkai Zhao

材料学院

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摘要

The production of hydrogen fuel by photocatalytic water splitting is a hot issue in solar-energy harvesting technologies. An ideal photocatalyst should display suitable band gap, adequate band-edge position, and high carrier mobility. In this paper, first-principles calculations were used to reveal the potential of 2D CoGeSe₃ monolayer as a promising photocatalyst in water splitting. Indeed, this monolayer demonstrates good dynamic and thermal stability, is insoluble in water, and can easily be synthesized. Its band gap anticipates visible- and ultraviolet-light absorption (at ~10⁵ cm⁻¹). The electron and hole mobility is 601 and 509 cm²V⁻¹s⁻¹, respectively. Good matching to the water redox potential in the neutral pH of water is also manifested.

源语言	英语
文章编号	150588
期刊	Applied Surface Science
卷	565
DOI	https://doi.org/10.1016/j.apsusc.2021.150588
出版状态	已出版 - 1 11月 2021

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abstract = "The production of hydrogen fuel by photocatalytic water splitting is a hot issue in solar-energy harvesting technologies. An ideal photocatalyst should display suitable band gap, adequate band-edge position, and high carrier mobility. In this paper, first-principles calculations were used to reveal the potential of 2D CoGeSe3 monolayer as a promising photocatalyst in water splitting. Indeed, this monolayer demonstrates good dynamic and thermal stability, is insoluble in water, and can easily be synthesized. Its band gap anticipates visible- and ultraviolet-light absorption (at ~105 cm−1). The electron and hole mobility is 601 and 509 cm2V−1s−1, respectively. Good matching to the water redox potential in the neutral pH of water is also manifested.",

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author = "Abdul Jalil and {Zafar Ilyas}, Syed and Simeon Agathopoulos and Ali Qureshi and Ishaq Ahmed and Tingkai Zhao",

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AU - Jalil, Abdul

AU - Zafar Ilyas, Syed

AU - Agathopoulos, Simeon

AU - Qureshi, Ali

AU - Ahmed, Ishaq

AU - Zhao, Tingkai

PY - 2021/11/1

Y1 - 2021/11/1

N2 - The production of hydrogen fuel by photocatalytic water splitting is a hot issue in solar-energy harvesting technologies. An ideal photocatalyst should display suitable band gap, adequate band-edge position, and high carrier mobility. In this paper, first-principles calculations were used to reveal the potential of 2D CoGeSe3 monolayer as a promising photocatalyst in water splitting. Indeed, this monolayer demonstrates good dynamic and thermal stability, is insoluble in water, and can easily be synthesized. Its band gap anticipates visible- and ultraviolet-light absorption (at ~105 cm−1). The electron and hole mobility is 601 and 509 cm2V−1s−1, respectively. Good matching to the water redox potential in the neutral pH of water is also manifested.

AB - The production of hydrogen fuel by photocatalytic water splitting is a hot issue in solar-energy harvesting technologies. An ideal photocatalyst should display suitable band gap, adequate band-edge position, and high carrier mobility. In this paper, first-principles calculations were used to reveal the potential of 2D CoGeSe3 monolayer as a promising photocatalyst in water splitting. Indeed, this monolayer demonstrates good dynamic and thermal stability, is insoluble in water, and can easily be synthesized. Its band gap anticipates visible- and ultraviolet-light absorption (at ~105 cm−1). The electron and hole mobility is 601 and 509 cm2V−1s−1, respectively. Good matching to the water redox potential in the neutral pH of water is also manifested.

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KW - Mobility

KW - Molecular dynamics

KW - Photo-catalysis

KW - Stability

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2D CoGeSe3 monolayer as a visible-light photocatalyst with high carrier mobility: Theoretical prediction

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2D CoGeSe₃ monolayer as a visible-light photocatalyst with high carrier mobility: Theoretical prediction