Cobalt phosphide nanoarrays with crystalline-amorphous hybrid phase for hydrogen production in universal-pH
- Authors
- Yoon, Hyunseok; Song, Hee Jo; Ju, Bobae; Kim, Dong-Wan
- Issue Date
- 9월-2020
- Publisher
- TSINGHUA UNIV PRESS
- Keywords
- cobalt phosphide; self-supporting; electrocatalyst; hydrogen evolution reaction; universal-pH; large-scale
- Citation
- NANO RESEARCH, v.13, no.9, pp.2469 - 2477
- Indexed
- SCIE
SCOPUS
- Journal Title
- NANO RESEARCH
- Volume
- 13
- Number
- 9
- Start Page
- 2469
- End Page
- 2477
- URI
- https://scholar.korea.ac.kr/handle/2021.sw.korea/53641
- DOI
- 10.1007/s12274-020-2881-y
- ISSN
- 1998-0124
- Abstract
- To accomplish mass hydrogen production by electrochemical water-splitting, it is a necessary to develop robust, highly active, stable, and cost-effective hydrogen evolution reaction (HER) electrocatalysts that perform comparably to Pt in the universal pH range. In this work, cobalt phosphide hybrid nanosheets supported on carbon felt (CoP HNS/CF) are presented, which exhibit the superior electrocatalytic hydrogen production under a universal-pH. In these nanosheets, a single CoP HNS is composed of polycrystalline CoP and oxygen-enriched amorphous Co-O-P phase. Benefiting from its unique nanoarchitecture, as-fabricated CoP HNS/CF exhibits a tremendous electrocatalytic HER activity and outperforms Pt/C as well as state-of-the-art CoP electrocatalysts in universal-pH. In acidic and neutral media, the CoP HNS/CF shows superior electrocatalytic activity while maintaining its original hybrid crystalline-amorphous phase and morphology. In alkaline medium, the unexpected phase and morphological reorganization of CoP HNS/CF results in outstanding electrocatalytic operation. CoP HNS/CF not only achieves high electrocatalytic activity and kinetics, but also a stable and long operating lifetime even under a high current density of 500 mA.cm(-2). Furthermore, the fabrication of CoP HNS/CF can be scaled up easily, and the large CoP HNS/CF electrode also exhibits similar electrocatalytic activity and stability.
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Collections - College of Engineering > School of Civil, Environmental and Architectural Engineering > 1. Journal Articles
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