Crystal Facet Engineering of Photoelectrodes for Photoelectrochemical Water Splitting

Photoelectrochemical (PEC) water splitting is a promising approach for solar-driven hydrogen production with zero emissions, and it has been intensively studied over the past decades. However, the solar-to-hydrogen (STH) efficiencies of the current PEC systems are still far from the 10% target neede...

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Bibliographic Details
Published inChemical reviews Vol. 119; no. 8; pp. 5192 - 5247
Main Authors Wang, Songcan, Liu, Gang, Wang, Lianzhou
Format Journal Article
LanguageEnglish
Published United States American Chemical Society 24.04.2019
Subjects
adsorption
Charge transfer
Crystal structure
Crystals
electric field
Electric fields
electrical conductivity
Electrical resistivity
Engineering
Hydrogen production
photochemical reactions
Redox reactions
Semiconductor crystals
semiconductors
Surface reactions
Water splitting
zero emissions
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Abstract Photoelectrochemical (PEC) water splitting is a promising approach for solar-driven hydrogen production with zero emissions, and it has been intensively studied over the past decades. However, the solar-to-hydrogen (STH) efficiencies of the current PEC systems are still far from the 10% target needed for practical application. The development of efficient photoelectrodes in PEC systems holds the key to achieving high STH efficiencies. In recent years, crystal facet engineering has emerged as an important strategy in designing efficient photoelectrodes for PEC water splitting, which has yet to be comprehensively reviewed and is the main focus of this article. After the Introduction, the second section of this review concisely introduces the mechanisms of crystal facet engineering. The subsequent section provides a snapshot of the unique facet-dependent properties of some semiconductor crystals including surface electronic structures, redox reaction sites, surface built-in electric fields, molecular adsorption, photoreaction activity, photocorrosion resistance, and electrical conductivity. Then, the methods for fabricating photoelectrodes with faceted semiconductor crystals are reviewed, with a focus on the preparation processes. In addition, the notable advantages of the crystal facet engineering of photoelectrodes in terms of light harvesting, charge separation and transfer, and surface reactions are critically discussed. This is followed by a systematic overview of the modification strategies of faceted photoelectrodes to further enhance the PEC performance. The last section summarizes the major challenges and some invigorating perspectives for future research on crystal facet engineered photoelectrodes, which are believed to play a vital role in promoting the development of this important research field.
AbstractList Photoelectrochemical (PEC) water splitting is a promising approach for solar-driven hydrogen production with zero emissions, and it has been intensively studied over the past decades. However, the solar-to-hydrogen (STH) efficiencies of the current PEC systems are still far from the 10% target needed for practical application. The development of efficient photoelectrodes in PEC systems holds the key to achieving high STH efficiencies. In recent years, crystal facet engineering has emerged as an important strategy in designing efficient photoelectrodes for PEC water splitting, which has yet to be comprehensively reviewed and is the main focus of this article. After the Introduction, the second section of this review concisely introduces the mechanisms of crystal facet engineering. The subsequent section provides a snapshot of the unique facet-dependent properties of some semiconductor crystals including surface electronic structures, redox reaction sites, surface built-in electric fields, molecular adsorption, photoreaction activity, photocorrosion resistance, and electrical conductivity. Then, the methods for fabricating photoelectrodes with faceted semiconductor crystals are reviewed, with a focus on the preparation processes. In addition, the notable advantages of the crystal facet engineering of photoelectrodes in terms of light harvesting, charge separation and transfer, and surface reactions are critically discussed. This is followed by a systematic overview of the modification strategies of faceted photoelectrodes to further enhance the PEC performance. The last section summarizes the major challenges and some invigorating perspectives for future research on crystal facet engineered photoelectrodes, which are believed to play a vital role in promoting the development of this important research field.
Photoelectrochemical (PEC) water splitting is a promising approach for solar-driven hydrogen production with zero emissions, and it has been intensively studied over the past decades. However, the solar-to-hydrogen (STH) efficiencies of the current PEC systems are still far from the 10% target needed for practical application. The development of efficient photoelectrodes in PEC systems holds the key to achieving high STH efficiencies. In recent years, crystal facet engineering has emerged as an important strategy in designing efficient photoelectrodes for PEC water splitting, which has yet to be comprehensively reviewed and is the main focus of this article. After the Introduction, the second section of this review concisely introduces the mechanisms of crystal facet engineering. The subsequent section provides a snapshot of the unique facet-dependent properties of some semiconductor crystals including surface electronic structures, redox reaction sites, surface built-in electric fields, molecular adsorption, photoreaction activity, photocorrosion resistance, and electrical conductivity. Then, the methods for fabricating photoelectrodes with faceted semiconductor crystals are reviewed, with a focus on the preparation processes. In addition, the notable advantages of the crystal facet engineering of photoelectrodes in terms of light harvesting, charge separation and transfer, and surface reactions are critically discussed. This is followed by a systematic overview of the modification strategies of faceted photoelectrodes to further enhance the PEC performance. The last section summarizes the major challenges and some invigorating perspectives for future research on crystal facet engineered photoelectrodes, which are believed to play a vital role in promoting the development of this important research field.Photoelectrochemical (PEC) water splitting is a promising approach for solar-driven hydrogen production with zero emissions, and it has been intensively studied over the past decades. However, the solar-to-hydrogen (STH) efficiencies of the current PEC systems are still far from the 10% target needed for practical application. The development of efficient photoelectrodes in PEC systems holds the key to achieving high STH efficiencies. In recent years, crystal facet engineering has emerged as an important strategy in designing efficient photoelectrodes for PEC water splitting, which has yet to be comprehensively reviewed and is the main focus of this article. After the Introduction, the second section of this review concisely introduces the mechanisms of crystal facet engineering. The subsequent section provides a snapshot of the unique facet-dependent properties of some semiconductor crystals including surface electronic structures, redox reaction sites, surface built-in electric fields, molecular adsorption, photoreaction activity, photocorrosion resistance, and electrical conductivity. Then, the methods for fabricating photoelectrodes with faceted semiconductor crystals are reviewed, with a focus on the preparation processes. In addition, the notable advantages of the crystal facet engineering of photoelectrodes in terms of light harvesting, charge separation and transfer, and surface reactions are critically discussed. This is followed by a systematic overview of the modification strategies of faceted photoelectrodes to further enhance the PEC performance. The last section summarizes the major challenges and some invigorating perspectives for future research on crystal facet engineered photoelectrodes, which are believed to play a vital role in promoting the development of this important research field.
Author Liu, Gang
Wang, Lianzhou
Wang, Songcan
AuthorAffiliation University of Science and Technology of China
Shenyang National Laboratory for Materials Science
School of Materials Science and Engineering
Nanomaterials Centre, School of Chemical Engineering and Australian Institute for Bioengineering and Nanotechnology
AuthorAffiliation_xml – name: University of Science and Technology of China
– name: Shenyang National Laboratory for Materials Science
– name: School of Materials Science and Engineering
– name: Nanomaterials Centre, School of Chemical Engineering and Australian Institute for Bioengineering and Nanotechnology
Author_xml – sequence: 1
  givenname: Songcan
  orcidid: 0000-0002-3848-1191
  surname: Wang
  fullname: Wang, Songcan
  organization: Nanomaterials Centre, School of Chemical Engineering and Australian Institute for Bioengineering and Nanotechnology
– sequence: 2
  givenname: Gang
  orcidid: 0000-0002-6946-7552
  surname: Liu
  fullname: Liu, Gang
  email: gangliu@imr.ac.cn
  organization: University of Science and Technology of China
– sequence: 3
  givenname: Lianzhou
  orcidid: 0000-0002-5947-306X
  surname: Wang
  fullname: Wang, Lianzhou
  email: l.wang@uq.edu.au
  organization: Nanomaterials Centre, School of Chemical Engineering and Australian Institute for Bioengineering and Nanotechnology
BackLink https://www.ncbi.nlm.nih.gov/pubmed/30875200$$D View this record in MEDLINE/PubMed
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Snippet Photoelectrochemical (PEC) water splitting is a promising approach for solar-driven hydrogen production with zero emissions, and it has been intensively...
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SubjectTerms adsorption
Charge transfer
Crystal structure
Crystals
electric field
Electric fields
electrical conductivity
Electrical resistivity
Engineering
Hydrogen production
photochemical reactions
Redox reactions
Semiconductor crystals
semiconductors
Surface reactions
Water splitting
zero emissions
Title Crystal Facet Engineering of Photoelectrodes for Photoelectrochemical Water Splitting
URI http://dx.doi.org/10.1021/acs.chemrev.8b00584
https://www.ncbi.nlm.nih.gov/pubmed/30875200
https://www.proquest.com/docview/2216259505
https://www.proquest.com/docview/2193162654
https://www.proquest.com/docview/2237538036
Volume 119
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