In Situ Photodeposition of Cobalt Phosphate (CoHPO) on CdInS Photocatalyst for Accelerated Hole Extraction and Improved Hydrogen Evolution

Overview

Journal Nanomaterials (Basel)

Date 2023 Feb 11

PMID 36770380

Authors

Jiachen Xu

Qinran Li

Dejian Sui

Wei Jiang

Fengqi Liu

Xiuquan Gu

Yulong Zhao

Pengzhan Ying

Liang Mao

Xiaoyan Cai

Junying Zhang

Affiliations

Soon will be listed here.

Abstract

The ternary metal sulfide CdInS (CIS) has great application potential in solar-to-hydrogen conversion due to its suitable band gap, good stability and low cost. However, the photocatalytic hydrogen (H) evolution performance of CIS is severely limited by the rapid electron-hole recombination originating from the slow photogenerated hole transfer kinetics. Herein, by simply depositing cobalt phosphate (CoHPO, noted as Co-Pi), a non-precious co-catalyst, an efficient pathway for accelerating the hole transfer process and subsequently promoting the H evolution reaction (HER) activity of CIS nanosheets is developed. X-ray photoelectron spectroscopy (XPS) reveals that the Co atoms of Co-Pi preferentially combine with the unsaturated S atoms of CIS to form Co-S bonds, which act as channels for fast hole extraction from CIS to Co-Pi. Electron paramagnetic resonance (EPR) and time-resolved photoluminescence (TRPL) showed that the introduction of Co-Pi on ultrathin CIS surface not only increases the probability of photogenerated holes arriving the catalyst surface, but also prolongs the charge carrier's lifetime by reducing the recombination of electrons and holes. Therefore, Co-Pi/CIS exhibits a satisfactory photocatalytic H evolution rate of 7.28 mmol g h under visible light, which is superior to the pristine CIS (2.62 mmol g h) and Pt modified CIS (3.73 mmol g h).

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