Current understanding and challenges of solar-driven hydrogen generation using polymeric photocatalysts

Yiou Wang; Anastasia Vogel; Michael Sachs; Reiner Sebastian Sprick; Liam Wilbraham; Savio J.A. Moniz; Robert Godin; Martijn A. Zwijnenburg; James R. Durrant; Andrew I. Cooper; Junwang Tang

doi:10.1038/s41560-019-0456-5

Current understanding and challenges of solar-driven hydrogen generation using polymeric photocatalysts

Yiou Wang, Anastasia Vogel, Michael Sachs, Reiner Sebastian Sprick, Liam Wilbraham, Savio J.A. Moniz, Robert Godin, Martijn A. Zwijnenburg, James R. Durrant, Andrew I. Cooper, Junwang Tang^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

715 Citations (Scopus)

Abstract

The use of hydrogen as a fuel, when generated from water using semiconductor photocatalysts and driven by sunlight, is a sustainable alternative to fossil fuels. Polymeric photocatalysts are based on Earth-abundant elements and have the advantage over their inorganic counterparts in that their electronic properties are easily tuneable through molecular engineering. Polymeric photocatalysts have developed rapidly over the past decade, resulting in the discovery of many active materials. However, our understanding of the key properties underlying their photoinitiated redox processes has not kept pace, and this impedes further progress to generate cost-competitive technologies. Here, we discuss state-of-the-art polymeric photocatalysts and our microscopic understanding of their activities. We conclude with a discussion of five outstanding challenges in this field: non-standardized reporting of activities, limited photochemical stability, insufficient knowledge of reaction mechanisms, balancing charge carrier lifetimes with catalysis timescales and the use of unsustainable sacrificial reagents.

Original language	English
Pages (from-to)	746-760
Number of pages	15
Journal	Nature Energy
Volume	4
Issue number	9
DOIs	https://doi.org/10.1038/s41560-019-0456-5
Publication status	Published - 1 Sept 2019
Externally published	Yes

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title = "Current understanding and challenges of solar-driven hydrogen generation using polymeric photocatalysts",

abstract = "The use of hydrogen as a fuel, when generated from water using semiconductor photocatalysts and driven by sunlight, is a sustainable alternative to fossil fuels. Polymeric photocatalysts are based on Earth-abundant elements and have the advantage over their inorganic counterparts in that their electronic properties are easily tuneable through molecular engineering. Polymeric photocatalysts have developed rapidly over the past decade, resulting in the discovery of many active materials. However, our understanding of the key properties underlying their photoinitiated redox processes has not kept pace, and this impedes further progress to generate cost-competitive technologies. Here, we discuss state-of-the-art polymeric photocatalysts and our microscopic understanding of their activities. We conclude with a discussion of five outstanding challenges in this field: non-standardized reporting of activities, limited photochemical stability, insufficient knowledge of reaction mechanisms, balancing charge carrier lifetimes with catalysis timescales and the use of unsustainable sacrificial reagents.",

author = "Yiou Wang and Anastasia Vogel and Michael Sachs and Sprick, {Reiner Sebastian} and Liam Wilbraham and Moniz, {Savio J.A.} and Robert Godin and Zwijnenburg, {Martijn A.} and Durrant, {James R.} and Cooper, {Andrew I.} and Junwang Tang",

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AU - Wang, Yiou

AU - Vogel, Anastasia

AU - Sachs, Michael

AU - Sprick, Reiner Sebastian

AU - Wilbraham, Liam

AU - Moniz, Savio J.A.

AU - Godin, Robert

AU - Zwijnenburg, Martijn A.

AU - Durrant, James R.

AU - Cooper, Andrew I.

AU - Tang, Junwang

PY - 2019/9/1

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N2 - The use of hydrogen as a fuel, when generated from water using semiconductor photocatalysts and driven by sunlight, is a sustainable alternative to fossil fuels. Polymeric photocatalysts are based on Earth-abundant elements and have the advantage over their inorganic counterparts in that their electronic properties are easily tuneable through molecular engineering. Polymeric photocatalysts have developed rapidly over the past decade, resulting in the discovery of many active materials. However, our understanding of the key properties underlying their photoinitiated redox processes has not kept pace, and this impedes further progress to generate cost-competitive technologies. Here, we discuss state-of-the-art polymeric photocatalysts and our microscopic understanding of their activities. We conclude with a discussion of five outstanding challenges in this field: non-standardized reporting of activities, limited photochemical stability, insufficient knowledge of reaction mechanisms, balancing charge carrier lifetimes with catalysis timescales and the use of unsustainable sacrificial reagents.

AB - The use of hydrogen as a fuel, when generated from water using semiconductor photocatalysts and driven by sunlight, is a sustainable alternative to fossil fuels. Polymeric photocatalysts are based on Earth-abundant elements and have the advantage over their inorganic counterparts in that their electronic properties are easily tuneable through molecular engineering. Polymeric photocatalysts have developed rapidly over the past decade, resulting in the discovery of many active materials. However, our understanding of the key properties underlying their photoinitiated redox processes has not kept pace, and this impedes further progress to generate cost-competitive technologies. Here, we discuss state-of-the-art polymeric photocatalysts and our microscopic understanding of their activities. We conclude with a discussion of five outstanding challenges in this field: non-standardized reporting of activities, limited photochemical stability, insufficient knowledge of reaction mechanisms, balancing charge carrier lifetimes with catalysis timescales and the use of unsustainable sacrificial reagents.

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Current understanding and challenges of solar-driven hydrogen generation using polymeric photocatalysts

Abstract

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