Twin Structure in BiVO4 Photoanodes Boosting Water Oxidation Performance through Enhanced Charge Separation and Transport
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Title
Twin Structure in BiVO4
Photoanodes Boosting Water Oxidation Performance through Enhanced Charge Separation and Transport
Authors
Keywords
-
Journal
Advanced Energy Materials
Volume 8, Issue 32, Pages 1802198
Publisher
Wiley
Online
2018-10-06
DOI
10.1002/aenm.201802198
References
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- (2017) Kristine Tolod et al. Catalysts
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