Abstract
Water electrolysis is an efficient way for hydrogen production. Finding efficient, cheap, and eco-friendly electrocatalysts is essential to the development of this technology. In the work, we present a first-principles study on the effects of tension on the hydrogen evolution reaction of a novel electrocatalyst, vanadium disulfide (VS2) monolayer. Two electrocatalytic processes, individual and collective processes, are investigated. We show that the catalytic ability of VS2 monolayer at higher hydrogen coverage can be efficiently improved by escalating tension. We find that the individual process is easier to occur in a wide range of hydrogen coverage and the collective process is possible at a certain hydrogen coverage under the same tension. The best hydrogen evolution reaction with near-zero Gibbs free energy can be achieved by tuning tension. We further show that the change of catalytic activity with tension and hydrogen coverage is induced by the change of free carrier density around the Fermi level, that is, higher carrier density, better catalytic performance. It is expected that tension can be a simple way to improve the catalytic activity, leading to the design of novel electrocatalysts for efficient hydrogen production from water electrolysis.
Highlights
Hydrogen, as an important energy carrier, is considered as a replacement of fossil fuels because of its abundant, clean, and renewable characteristics [1, 2]
We carry out first-principles to investigate the effects of tension on the hydrogen evolution reduction of VS2 monolayer
We find that tension can tune the hydrogen evolution reaction (HER) performance of VS2 monolayer at different hydrogen coverage
Summary
As an important energy carrier, is considered as a replacement of fossil fuels because of its abundant, clean, and renewable characteristics [1, 2]. Hydrogen production can be realized by photo-driven or electricaldriven water splitting [3,4,5,6,7], stream reforming [8], natural gas oxidization [9], carbonation [10], biomass electrolysis [11, 12], etc. To improve production efficiency and reduce cost, the design and fabrication of highly active, stable, and cheap electrocatalysts are critical to the development of green energy technology. It is well-known that noble metals and their alloys, such as platinum, are the most efficient catalysts in water electrolysis [16,17,18,19,20,21,22]. Its performance is reduced at high hydrogen coverage because
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