Surface Restructuring of Nickel Sulfide Generates Optimally-Coordinated Active Sites for ORR Catalysis
Bing Yan, Dilip Krishnamurthy, Christopher H. Hendon and, Siddharth Deshpande, Yogesh Surendranath, Venkatasubramanian, Viswanathan

TL;DR
This study reveals how surface restructuring of Ni3S2 creates active amorphous NiS layers with optimal Ni-S coordination for oxygen reduction, advancing understanding of metal-chalcogenide electrocatalysts.
Contribution
It demonstrates that Ni3S2 undergoes self-limiting surface restructuring forming amorphous NiS layers that enhance ORR catalysis, providing a new framework for surface chemistry analysis.
Findings
Ni3S2 forms a ~2 nm amorphous NiS surface film during catalysis.
Surface Ni-S coordination correlates with catalytic activity.
Amorphous NiS provides an optimal environment for ORR.
Abstract
First-row transition metal oxides and chalcogenides have been found to rival the performance of precious metal-based catalysts for the interconversion of water and O. The high lability of the first-row transition metal ions leads to surface dynamics under the conditions of catalysis and results in active site structures distinct from those expected by surface termination of the bulk lattice. While these surface transformations have been well-characterized on many metal oxides, the surface dynamics of heavier chalcogenides under electrocatalytic conditions are largely unknown. We recently reported that the heazlewoodite NiS bulk phase supports efficient ORR catalysis under benign aqueous conditions and exhibits excellent tolerance to electrolyte anions such as phosphate which poison Pt. Herein, we combine electrochemistry, surface spectroscopy and high resolution microscopy…
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