Recent Advances in Cu‐Based Cocatalysts toward Solar‐to‐Hydrogen Evolution: Categories and Roles

Zhu, Jiaxin; Cheng, Gang; Xiong, Jinyan; Li, Weijie; Dou, Shi Xue

doi:10.1002/solr.201900256

Cited by 46 publications

(21 citation statements)

References 159 publications

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“…It is a major challenge to utilize solar energy for water splitting. Based on the thermodynamic requirement, the CB and VB potentials should be more negative than the reduction potential of H 2 O (0 V vs NHE) for H 2 generation and more positive than the oxidation potential of H 2 O (1.23 V vs NHE) for O 2 generation . The pure 2D TNMOs generally show the relatively low photocatalytic efficiency for water splitting due to the limited light‐harvesting ability, relatively low specific surface area, and separation rate of charge carriers.…”

Section: Photocatalytic Applicationsmentioning

confidence: 99%

2D Titanium/Niobium Metal Oxide‐Based Materials for Photocatalytic Application

et al. 2020

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2D titanium/niobium (Ti/Nb) metal oxide (TNMO)‐based compounds have attracted increasing attention due to the fact that the contained octahedral structure of Ti4+‐based TiO6 and/or Nb5+‐based NbO6 can be facilely modified so as to achieve an enhanced photocatalytic performance for environmental remediation and energy conversion. Herein, the different synthetic methods for the construction of various 2D TNMO‐based photocatalysts are presented. Many basic principles, such as nanostructure design, doping, and construction of heterojunctions, are introduced to enhance the photocatalytic performance of 2D TNMO compounds. The relationship between the photocatalytic performance and regulation methods is also described. Furthermore, the photocatalytic applications of 2D TNMO‐based materials are discussed, including H2 generation, removal of pollutants, CO2 reduction, nitrogen photofixation, disinfection, and organic synthesis. Finally, the challenges and future development of 2D TNMO‐based materials are also discussed.

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Section: Photocatalytic Applicationsmentioning

confidence: 99%

2D Titanium/Niobium Metal Oxide‐Based Materials for Photocatalytic Application

et al. 2020

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“…Generally, solar energy conversion system always involves three different steps about charge generation, charge separation, and catalytic reactions . A substantial proportion of the efforts were conducted to exploit the promising semiconductors . However, the low efficiency is mainly ascribed to wide bandgap, poor charge transfer, and poor stability.…”

Section: Introductionmentioning

confidence: 99%

Defect Engineering of Photocatalysts for Solar Energy Conversion

et al. 2020

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Solar energy conversion is one of the most versatile approaches for sustainable energy demands. The fundamental limitations for photocatalysis remain light absorption, charge separation, and photocatalytic (PC) performance of the catalysts. For the past few decades, defect engineering has been proven to be a promising solution for converting solar energy to chemical energy. In this regard, the recent progress of defect engineering toward solar energy conversion is summarized. Beginning with defects classification, the definition of various defects, synthesized strategies, and characterization techniques of controllable material defects are presented. The role of defect engineering on solar energy conversion is developed, extending light absorption, promoting charge separation, and facilitating stable PC reaction. The achievement of the defective photocatalysts is discussed toward versatile applications such as solar water splitting, CO2 reduction, nitrogen fixation, molecular activation, pollutants degradation, and solar cells. Finally, this Review, with regards to defect engineering, ends with the future opportunities and challenges for this exciting and emerging area for solar energy conversion.

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“…An efficient and low‐cost photocatalyst for hydrogen (H 2 ) production, particularly from water splitting using solar energy, is one of the most promising approaches for sustainable fuels production. [ 1–5 ] In a biological system, the formation and uptake of H 2 are carried out by hydrogenase (H 2 ase). [ 6–8 ] High‐resolution X‐ray crystallography reveals that the active center (called as H‐cluster) of natural H 2 ase, taking [FeFe]‐H 2 ase as an example, features a butterfly [Fe 2 S 2 ] subunit and a cubic [Fe 4 S 4 ] cluster.…”

Section: Introductionmentioning

confidence: 99%

Per‐6‐Thiol‐Cyclodextrin Engineered [FeFe]‐Hydrogenase Mimic/CdSe Quantum Dot Assembly for Photocatalytic Hydrogen Production

Jian

Wang

et al. 2020

Solar RRL

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[FeFe]‐hydrogenase ([FeFe]‐H2ase) mimics, inspired by hydrogenases in nature, have emerged as an important class of molecular catalysts toward hydrogen (H2) evolution. Herein, a per‐6‐thiol‐cyclodextrin (CDSH) engineered [FeFe]‐H2ase mimic/CdSe quantum dot (QD) assembly is established for effective photocatalytic H2 evolution. In the assembly, CDSH is first anchored on CdSe QDs via the strong multidentate Cd‐thiol coordination. Then, [FeFe]‐H2ase mimic is assembled on the QD surface via the host–guest supramolecular interaction between the hydrophobic cavity of cyclodextrin (CD) and the adamantyl (AD) group of [FeFe]‐H2ase mimic. In neutral aqueous solution of isopropanol, the Fe2S2‐AD/CDSH/CdSe assembly exhibits a turnover number (TON) of 1.12 × 105 (based on Fe2S2‐AD) under visible light, which is about 12‐fold to the corresponding system without CDSH. Mechanistic insights indicate that the CDSH can not only prevent the aggregation of QDs in acidic conditions, but also balance the interfacial charge (electron and hole) transfer to avoid the photocorrosion of QDs, thereby giving the highest TON of H2 photogeneration based on [FeFe]‐H2ase mimics up to date.

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Recent Advances in Cu‐Based Cocatalysts toward Solar‐to‐Hydrogen Evolution: Categories and Roles

Cited by 46 publications

References 159 publications

2D Titanium/Niobium Metal Oxide‐Based Materials for Photocatalytic Application

2D Titanium/Niobium Metal Oxide‐Based Materials for Photocatalytic Application

Defect Engineering of Photocatalysts for Solar Energy Conversion

Per‐6‐Thiol‐Cyclodextrin Engineered [FeFe]‐Hydrogenase Mimic/CdSe Quantum Dot Assembly for Photocatalytic Hydrogen Production

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