Chapter 2: Theoretical Design of PEC Materials

Junjie Wang; Pakpoom Reunchan; Wei Zhou; Naoto Umezawa

doi:10.1039/9781782629863-00029

Chapter 2: Theoretical Design of PEC Materials

Junjie Wang, Pakpoom Reunchan, Wei Zhou, Naoto Umezawa

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

This chapter discusses the computational design of inorganic photoelectrochemical (PEC) materials. The electronic structure of photoanodes and photocathodes significantly affect photoabsorption, carrier transport, and water redox properties. Adjusting the band edge positions with respect to redox potentials is, therefore, an important task for the design of photocatalysts for PEC application. We present our recent attempts on the band edge engineering of semiconductor photocatalysts using density functional theory (DFT) calculations. First, we discuss the effects of doping on visible light absorption as well as introduction of conductive carriers. Second, we demonstrate how the band edge positions are controlled by biaxial strain. Third, we present our studies on an evolutional crystal structure search for predicting novel photofunctional materials. These results demonstrate that modern DFT-based computational materials science is a powerful tool for finding promising PEC materials.

Original language	English
Title of host publication	Lignin Valorization
Subtitle of host publication	Emerging Approaches
Editors	S. David Tilley, Stephan Lany, Roel van de Krol
Publisher	Royal Society of Chemistry
Pages	29-61
Number of pages	33
Edition	20
ISBN (Electronic)	9781782620426, 9781782625544, 9781782629252
DOIs	https://doi.org/10.1039/9781782629863-00029
State	Published - 2018
Externally published	Yes

Publication series

Name	RSC Energy and Environment Series
Number	20
Volume	2018-January
ISSN (Print)	2044-0774
ISSN (Electronic)	2044-0782

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10.1039/9781782629863-00029

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title = "Chapter 2: Theoretical Design of PEC Materials",

abstract = "This chapter discusses the computational design of inorganic photoelectrochemical (PEC) materials. The electronic structure of photoanodes and photocathodes significantly affect photoabsorption, carrier transport, and water redox properties. Adjusting the band edge positions with respect to redox potentials is, therefore, an important task for the design of photocatalysts for PEC application. We present our recent attempts on the band edge engineering of semiconductor photocatalysts using density functional theory (DFT) calculations. First, we discuss the effects of doping on visible light absorption as well as introduction of conductive carriers. Second, we demonstrate how the band edge positions are controlled by biaxial strain. Third, we present our studies on an evolutional crystal structure search for predicting novel photofunctional materials. These results demonstrate that modern DFT-based computational materials science is a powerful tool for finding promising PEC materials.",

author = "Junjie Wang and Pakpoom Reunchan and Wei Zhou and Naoto Umezawa",

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year = "2018",

doi = "10.1039/9781782629863-00029",

language = "英语",

series = "RSC Energy and Environment Series",

publisher = "Royal Society of Chemistry",

number = "20",

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booktitle = "Lignin Valorization",

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Chapter 2: Theoretical Design of PEC Materials. / Wang, Junjie; Reunchan, Pakpoom; Zhou, Wei et al.
Lignin Valorization: Emerging Approaches. ed. / S. David Tilley; Stephan Lany; Roel van de Krol. 20. ed. Royal Society of Chemistry, 2018. p. 29-61 (RSC Energy and Environment Series; Vol. 2018-January, No. 20).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

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AU - Reunchan, Pakpoom

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Y1 - 2018

N2 - This chapter discusses the computational design of inorganic photoelectrochemical (PEC) materials. The electronic structure of photoanodes and photocathodes significantly affect photoabsorption, carrier transport, and water redox properties. Adjusting the band edge positions with respect to redox potentials is, therefore, an important task for the design of photocatalysts for PEC application. We present our recent attempts on the band edge engineering of semiconductor photocatalysts using density functional theory (DFT) calculations. First, we discuss the effects of doping on visible light absorption as well as introduction of conductive carriers. Second, we demonstrate how the band edge positions are controlled by biaxial strain. Third, we present our studies on an evolutional crystal structure search for predicting novel photofunctional materials. These results demonstrate that modern DFT-based computational materials science is a powerful tool for finding promising PEC materials.

AB - This chapter discusses the computational design of inorganic photoelectrochemical (PEC) materials. The electronic structure of photoanodes and photocathodes significantly affect photoabsorption, carrier transport, and water redox properties. Adjusting the band edge positions with respect to redox potentials is, therefore, an important task for the design of photocatalysts for PEC application. We present our recent attempts on the band edge engineering of semiconductor photocatalysts using density functional theory (DFT) calculations. First, we discuss the effects of doping on visible light absorption as well as introduction of conductive carriers. Second, we demonstrate how the band edge positions are controlled by biaxial strain. Third, we present our studies on an evolutional crystal structure search for predicting novel photofunctional materials. These results demonstrate that modern DFT-based computational materials science is a powerful tool for finding promising PEC materials.

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Chapter 2: Theoretical Design of PEC Materials

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