Dislocation-engineered piezocatalytic water splitting in single-crystal BaTiO3

Yan Zhang; Kaiyu Feng; Miao Song; Shan Xiang; Yan Zhao; Hanyu Gong; Fan Ni; Felix Dietrich; Lovro Fulanović; Fangping Zhuo; Gerd  Buntkowsky; Till Frömling; Dou Zhang; Chris Bowen; Jürgen Rödel

doi:10.1039/d4ee03789h

Dislocation-engineered piezocatalytic water splitting in single-crystal BaTiO3

Yan Zhang, Kaiyu Feng, Miao Song, Shan Xiang, Yan Zhao, Hanyu Gong, Fan Ni, Felix Dietrich, Lovro Fulanović, Fangping Zhuo, Gerd Buntkowsky, Till Frömling, Dou Zhang, Chris Bowen, Jürgen Rödel

Centre for Integrated Materials, Processes & Structures (IMPS)

Research output: Contribution to journal › Article › peer-review

2 Citations (SciVal)

Abstract

The rapid development of society has exacerbated energy scarcity, making water splitting a promising solution for humanity to produce green hydrogen. Therefore, enhancing the relatively low catalytic performance of piezoelectric bulk catalysts is crucial to unlocking their potential for broader practical applications and potentially alleviating contemporary energy demands. Here, we introduce a sustainable doping strategy that deliberately imprints dislocations and their associated strain fields without additional elements into barium titanate single crystals to address the challenges faced by bulk piezoelectric catalysts. The presence of highly-oriented {100}〈100〉 dislocations in plastically deformed materials was observed utilizing bright-field transmission electron microscopy. The strains induced by dislocations were mapped using high-angle annular dark-field and geometric phase analysis techniques. According to experimental observations and density functional theory calculations, the deformed materials exhibit superior performance in terms of electrical conductivity, ultrasonic response, and hydrogen adsorption-free energy. As result a nearly fivefold increase in piezoelectric catalytic performance, as compared to undeformed reference materials, is achieved. Our work demonstrates the potential of dislocation engineering to boost bulk piezoelectric catalysts, thereby challenging the current reliance on powder-based catalysts.

Original language	English
Pages (from-to)	602-612
Journal	Energy & Environmental Science
Volume	18
Issue number	2
Early online date	10 Dec 2024
DOIs	https://doi.org/10.1039/d4ee03789h
Publication status	Published - 21 Jan 2025

Data Availability Statement

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Funding

Y. Z. acknowledges support from the National Key Research and Development Program (2022YFB3807404), the National Natural Science Foundation of China (no. 52302158), Xiaomi Young Talents Program and Humboldt Research Fellowship for Experienced Researchers (Dr Yan Zhang). J. R. acknowledges funding from the German Research Foundation (DFG) under project no. 414179371. F. Z. acknowledges support from the Alexander von Humboldt Foundation for the fellowship with award number 1203828 and the DFG through project no. 530438323. G. B. acknowledges funding from the DFG under contract Bu-911-28-2. C. B. acknowledges support of UKRI Frontier Research Guarantee on \u201CProcessing of Smart Porous Electro-Ceramic Transducers \u2013 ProSPECT\u201D, Project No. EP/X023265/1. We thank Professor K. Durst for access to the LEXT laser scanning microscope. We appreciate Phadcalc ( https://www.phadcalc.com ) for the excellent TEM service.

Funders	Funder number
National Key Research and Development Program of China	2022YFB3807404
Alexander von Humboldt-Stiftung	Bu-911-28-2, 1203828, 530438323
National Natural Science Foundation of China	52302158
Deutsche Forschungsgemeinschaft	414179371
UK Research and Innovation	EP/X023265/1

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abstract = "The rapid development of society has exacerbated energy scarcity, making water splitting a promising solution for humanity to produce green hydrogen. Therefore, enhancing the relatively low catalytic performance of piezoelectric bulk catalysts is crucial to unlocking their potential for broader practical applications and potentially alleviating contemporary energy demands. Here, we introduce a sustainable doping strategy that deliberately imprints dislocations and their associated strain fields without additional elements into barium titanate single crystals to address the challenges faced by bulk piezoelectric catalysts. The presence of highly-oriented {100}〈100〉 dislocations in plastically deformed materials was observed utilizing bright-field transmission electron microscopy. The strains induced by dislocations were mapped using high-angle annular dark-field and geometric phase analysis techniques. According to experimental observations and density functional theory calculations, the deformed materials exhibit superior performance in terms of electrical conductivity, ultrasonic response, and hydrogen adsorption-free energy. As result a nearly fivefold increase in piezoelectric catalytic performance, as compared to undeformed reference materials, is achieved. Our work demonstrates the potential of dislocation engineering to boost bulk piezoelectric catalysts, thereby challenging the current reliance on powder-based catalysts.",

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AU - Ni, Fan

AU - Dietrich, Felix

AU - Fulanović, Lovro

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AU - Buntkowsky, Gerd

AU - Frömling, Till

AU - Zhang, Dou

AU - Bowen, Chris

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Dislocation-engineered piezocatalytic water splitting in single-crystal BaTiO3

Abstract

Data Availability Statement

Funding

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