Abstract
The demand for renewable energy resources has led to the development of water electrolysis technology. Various transitional metal chalcogenides are investigated to adopt water electrolysis. Nickel telluride, from the family of transition metal chalcogenides, is attractive as a new cathode material for the hydrogen evolution reaction due to its metallic property. However, conventional approaches mainly focus on the solvothermal method and these have difficulty in controlling the alignment of nickel telluride. Therefore, another route to synthesize this material is necessary. In this study, for the first time, a radio-frequency (RF) magnetron sputtering method is used to synthesize a nickel telluride thin film and this method has the benefit of controlling the alignment of the nickel telluride thin film. By RF magnetron sputtering, a nickel telluride thin film is deposited on the substrate along the direction normal to the plane of the substrate, forming a columnar structure with vertical alignment. Its microstructure enables fast flow of electrons, having the advantage of hydrogen evolution reaction as a cathode material. The sample in optimized conditions shows a good performance with an overpotential of 416 mV and a Tafel slope of 63.79 mV dec−1. Therefore, the RF magnetron sputtering method can be adopted as a new approach to synthesize a vertically aligned electrocatalyst.
Highlights
INTRODUCTIONScitation.org/journal/apm nature reduce the possibilities for commercialization and device applications
In recent times, the largest component of worldwide energy resources has come from carbon-based fossil fuels, which contribute to climate change
A vertically grown nickel telluride thin film was synthesized by RF magnetron sputtering, and its electrochemical performance for hydrogen evolution reaction (HER) in a strongly acidic medium was evaluated
Summary
Scitation.org/journal/apm nature reduce the possibilities for commercialization and device applications.. Anantharaj et al reported that NiTe2 nanowires could be an alternative to platinum for HER applications, demonstrating lower overpotential than platinum foil in extreme pH conditions, viz., 0 and 14.25 NiTe2 is widely applied to detect organic compounds, supercapacitors, and batteries, based on its high electrical conductivity, fast electron transmission, and magnetic property. These results indicate that mass production and synthesis of large-scale NiTe2 should be required for wider application. We suggest the possibility that the wafer-scale vertically grown NiTe2 thin film on an arbitrary substrate shows a robust performance for hydrogen evolution reaction in extremely acidic conditions
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