Split water with practical application for better renewable energy solution

The photocatalytic water splitting process holds appeal for scientists as a solution to both energy and environmental problems. In this process, water is split into oxygen and hydrogen using light energy and a catalyst. As the problem of global warming has increased, researchers have looked to hydrogen, a clean-burning fuel, as a renewable energy solution. With water being such an inexpensive resource, tremendous effort has been dedicated to this promising research field during the past decades. But scientists have only been able to discover a few photocatalysts with both high efficiency and excellent stability. So the photocatalytic water splitting technology still has a long way to go until practical application is possible.

 

A research team from Xi’an Jiaotong University in China has achieved excellent results using an inorganic compound called bismuth vanadate (BiVO₄) crystals as a photocatalyst to achieve efficient photocatalytic water splitting. Their work show the close relationship between the surface properties of the BiVO₄ and the photocatalytic activity achieved. The team’s findings are published in the journal Nano Research on August 15, 2022.

 

For the water splitting process to be efficient, separation of the electron-hole pair and their consumption by water oxidation or water reduction reactions taking place on the surface is essential. The electron-hole is a charge carrier responsible for creating electric current in semiconducting materials. Charge-carrier refers to a particle that moves freely within a material and carries an electric charge. In recent years, scientists have achieved excellent performance by exposing specific facets as enriched reaction sites on the photocatalysts. Researchers have discovered that titanium dioxide and strontium titanate, with their exposed facets, offer excellent performance. This knowledge gave scientists clues that an efficient photocatalytic process could be achieved by tuning the surface of a photocatalyst with different functions.

 

In further research, scientists reported that BiVO₄ nanosheets with exposed facets exhibited excellent performance for water oxidation. Research suggested that if the BiVO₄ facets were enlarged, superior photocatalytic activity for water oxidation could be achieved.

 

The Xi’an Jiaotong University research team focused their attention on BiVO₄ as a model photocatalyst. They studied the crucial role of surface charge-carrier consumption on the water splitting reactions. The team fabricated BiVO₄ single crystals with a tailored ratio of facets for the reductive sites and the oxidative sites. They used a simple controlled hydrothermal method to synthesize the BiVO₄ crystal. Through this process, they demonstrated that efficient photocatalytic water oxidation could be achieved through balanced surface charge-carrier consumption that is based on a medium ratio of the reductive sites and the oxidative sites.

 

Using BiVO₄ alone as a typical photocatalyst for water oxidation does not achieve overall water splitting. So the researchers continued their study, constructing a Z-scheme system, where two different photocatalysts are combined. Using the BiVO₄ with appropriate cocatalysts, the team achieved efficient and stable photocatalytic overall water splitting.

 

“Superior photocatalytic water oxidation is obtained from BiVO₄ decahedrons with a medium ratio between reductive and oxidative sites, which is ascribed to the as-achieved balanced surficial charge-carrier consumption,” said Shaohua Shen, a professor in the International Research Center for Renewable Energy at Xi’an Jiaotong University. “In addition, efficient and stable photocatalytic overall water splitting is achieved by adopting the as-synthesized BiVO₄ decahedrons with suitable cocatalyst modification,” said Shen.

 

“Looking ahead, this work provides both guidance on the fabrication of nano/micro-material with controllable surficial morphology and insightful investigations of the corresponding photocatalytic redox reaction,” said Shen.

 

The research team includes Xiangjiu Guan, Li Tian, Jinwen Shi, Shaohua Shen from Xi’an Jiaotong University, and Yazhou Zhang from Xi’an Jiaotong University and Xiamen University.

 

The research is funded by the National Natural Science Foundation of China, the National Key Research and Development Program of China, the National Program for Support of Top-notch Young Professionals, the Natural Science Basic Research Program of Shaanxi Province, the Natural Science Foundation of Jiangsu Province, China Postdoctoral Science Foundation, the Fundamental Research Funds for the Central Universities, and The Youth Innovation Team of Shaanxi Universities.

 

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About Nano Research 

 

Nano Research is a peer-reviewed, international and interdisciplinary research journal, publishes all aspects of nano science and technology, featured in rapid review and fast publishing, sponsored by Tsinghua University and the Chinese Chemical Society. It offers readers an attractive mix of authoritative and comprehensive reviews and original cutting-edge research papers. After 15 years of development, it has become one of the most influential academic journals in the nano field. In 2022 InCites Journal Citation Reports, Nano Research has an Impact Factor of 10.269 (9.136, 5 years), the total cites reached 29620, ranking first in China’s international academic journals, and the number of highly cited papers reached 120, ranked among the top 2.8% of over 9000 academic journals.

 

About Tsinghua University Press

 

Established in 1980, belonging to Tsinghua University, Tsinghua University Press (TUP) is a leading comprehensive higher education and professional publisher in China. Committed to building a top-level global cultural brand, after 41 years of development, TUP has established an outstanding managerial system and enterprise structure, and delivered multimedia and multi-dimensional publications covering books, audio, video, electronic products, journals and digital publications. In addition, TUP actively carries out its strategic transformation from educational publishing to content development and service for teaching & learning and was named First-class National Publisher for achieving remarkable results.

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