A rational design of an efficient counter electrode with the Co/Co1P1N3atomic interface for promoting catalytic performance

Danni Zhou; Zhaoming Xia; Huishan Shang; Hai Xiao; Zhuoli Jiang; Haijing Li; Lirong Zheng; Juncai Dong; Wenxing Chen

doi:10.1039/d0qm00806k

A rational design of an efficient counter electrode with the Co/Co₁P₁N₃atomic interface for promoting catalytic performance

Danni Zhou, Zhaoming Xia, Huishan Shang, Hai Xiao, Zhuoli Jiang, Haijing Li, Lirong Zheng, Juncai Dong, Wenxing Chen^*

^*Corresponding author for this work

School of Material Science and Engineering

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

Interface engineering has been demonstrated to have a great effect on designing high performance catalysts. In particular, the interface design at the atomic scale is always a fortress to be overcome by researchers. Herein, we in situ introduced triphenylphosphine into cobalt atom sites in a metal-organic framework via encapsulation and successfully synthesized a cobalt single-atom catalyst with a co-coordinated atomic interface structure of P and N (Co/Co1P1N3). Adopted as a counter electrode (CE) in dye-sensitized solar cells (DSSCs), Co/Co1P1N3 demonstrates a power conversion efficiency (PCE) of 8.51%, outperforming Co/Co1N4 (6.62%) counter electrode and commercial Pt (7.88%). We discover that the electron donation from the P dopant can reduce the electrostatic attraction between Co and I- ions, which favor I- desorption processes, sequentially boosting the activity of Co/Co1P1N3.

Original language	English
Pages (from-to)	3085-3092
Number of pages	8
Journal	Materials Chemistry Frontiers
Volume	5
Issue number	7
DOIs	https://doi.org/10.1039/d0qm00806k
Publication status	Published - 7 Apr 2021

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title = "A rational design of an efficient counter electrode with the Co/Co1P1N3atomic interface for promoting catalytic performance",

abstract = "Interface engineering has been demonstrated to have a great effect on designing high performance catalysts. In particular, the interface design at the atomic scale is always a fortress to be overcome by researchers. Herein, we in situ introduced triphenylphosphine into cobalt atom sites in a metal-organic framework via encapsulation and successfully synthesized a cobalt single-atom catalyst with a co-coordinated atomic interface structure of P and N (Co/Co1P1N3). Adopted as a counter electrode (CE) in dye-sensitized solar cells (DSSCs), Co/Co1P1N3 demonstrates a power conversion efficiency (PCE) of 8.51\%, outperforming Co/Co1N4 (6.62\%) counter electrode and commercial Pt (7.88\%). We discover that the electron donation from the P dopant can reduce the electrostatic attraction between Co and I- ions, which favor I- desorption processes, sequentially boosting the activity of Co/Co1P1N3.",

author = "Danni Zhou and Zhaoming Xia and Huishan Shang and Hai Xiao and Zhuoli Jiang and Haijing Li and Lirong Zheng and Juncai Dong and Wenxing Chen",

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T1 - A rational design of an efficient counter electrode with the Co/Co1P1N3atomic interface for promoting catalytic performance

AU - Zhou, Danni

AU - Xia, Zhaoming

AU - Shang, Huishan

AU - Xiao, Hai

AU - Jiang, Zhuoli

AU - Li, Haijing

AU - Zheng, Lirong

AU - Dong, Juncai

AU - Chen, Wenxing

PY - 2021/4/7

Y1 - 2021/4/7

N2 - Interface engineering has been demonstrated to have a great effect on designing high performance catalysts. In particular, the interface design at the atomic scale is always a fortress to be overcome by researchers. Herein, we in situ introduced triphenylphosphine into cobalt atom sites in a metal-organic framework via encapsulation and successfully synthesized a cobalt single-atom catalyst with a co-coordinated atomic interface structure of P and N (Co/Co1P1N3). Adopted as a counter electrode (CE) in dye-sensitized solar cells (DSSCs), Co/Co1P1N3 demonstrates a power conversion efficiency (PCE) of 8.51%, outperforming Co/Co1N4 (6.62%) counter electrode and commercial Pt (7.88%). We discover that the electron donation from the P dopant can reduce the electrostatic attraction between Co and I- ions, which favor I- desorption processes, sequentially boosting the activity of Co/Co1P1N3.

AB - Interface engineering has been demonstrated to have a great effect on designing high performance catalysts. In particular, the interface design at the atomic scale is always a fortress to be overcome by researchers. Herein, we in situ introduced triphenylphosphine into cobalt atom sites in a metal-organic framework via encapsulation and successfully synthesized a cobalt single-atom catalyst with a co-coordinated atomic interface structure of P and N (Co/Co1P1N3). Adopted as a counter electrode (CE) in dye-sensitized solar cells (DSSCs), Co/Co1P1N3 demonstrates a power conversion efficiency (PCE) of 8.51%, outperforming Co/Co1N4 (6.62%) counter electrode and commercial Pt (7.88%). We discover that the electron donation from the P dopant can reduce the electrostatic attraction between Co and I- ions, which favor I- desorption processes, sequentially boosting the activity of Co/Co1P1N3.

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A rational design of an efficient counter electrode with the Co/Co₁P₁N₃atomic interface for promoting catalytic performance

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