Controlling basal plane sulfur vacancy in water splitting MoSx/NiF electrocatalysts through electric-field-assisted pulsed laser ablation

Chaudry Sajed Saraj; Subhash C Singh; Roshan Ali; Abhishek Shukla; Gopal Verma; Ting Ting Zou; Weili Yu; Wei Li; Chunlei Guo

doi:10.1016/j.isci.2023.106797

Controlling basal plane sulfur vacancy in water splitting MoSx/NiF electrocatalysts through electric-field-assisted pulsed laser ablation

iScience. 2023 May 4;26(6):106797. doi: 10.1016/j.isci.2023.106797. eCollection 2023 Jun 16.

Authors

Chaudry Sajed Saraj^{1

2}, Subhash C Singh³, Roshan Ali^{1

2}, Abhishek Shukla¹, Gopal Verma¹, Ting Ting Zou¹, Weili Yu¹, Wei Li^{1

2}, Chunlei Guo³

Affiliations

¹ GPL Photonics Laboratory, State Key Laboratory of Luminescence and Applications, Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun, Jilin 130033, P. R. China.
² University of Chinese Academy of Sciences (UCAS), Beijing 100049, China.
³ The Institute of Optics, University of Rochester, Rochester, NY 14627, USA.

Abstract

Eco-friendly, efficient, and durable electrocatalysts from earth-abundant materials are crucial for water splitting through hydrogen and oxygen generation. However, available methods to fabricate electrocatalysts are either hazardous and time-consuming or require expensive equipment, hindering the large-scale, eco-friendly production of artificial fuels. Here, we present a rapid, single-step method for producing MoS_x/NiF electrocatalysts with controlled sulfur-vacancies via electric-field-assisted pulsed laser ablation (EF-PLA) in liquid and in-situ deposition on nickel foam, enabling efficient water splitting. Electric-field parameters efficiently control S-vacancy active sites in electrocatalysts. Higher electric fields yield a MoS_x/NiF electrocatalyst with a larger density of S-vacancy sites, suited for HER due to lower Gibbs free energy for H∗ adsorption, while lower electric fields produce an electrocatalyst with lower S-vacancy sites, better suited for OER, as shown by both experimental and theoretical results. The present work opens a horizon in designing high-efficiency catalysts, for a wide range of chemical reactions.

Keywords: Chemistry; Electrochemistry; Materials chemistry; Materials science.