Issue 19, 2023

Amorphous CoB layer cooperates with piezoelectric polarization to boost carrier separation of Bi2WO6 for efficient piezo-PEC performance

Abstract

Poor surface charge reaction efficiency and conductivity limit the further application of Bi2WO6 in piezoelectric photocatalytic water splitting. Amorphous cobalt–boron (CoB) layers were deposited on bismuth tungstate nanoplates by photo-assisted electrodeposition. The presence of an amorphous CoB layer accelerates the charge transport and water oxidation kinetics, resulting in a greatly enhanced photocurrent with the reversible hydrogen electrode, with a photocurrent density of about 0.288 mA cm−2 at 1.23 V vs. RHE, more than three times that of the pure Bi2WO6 photoelectrode. Under ultrasonic conditions, the photocurrent of Bi2WO6/CoB-2 is further increased to 0.382 mA cm−2, which is almost 3.5 times that of pure Bi2WO6 under the same conditions. The detailed experimental data show that the amorphous cobalt–boron layer not only effectively reduces the hole accumulation on the surface of the photoelectrode and improves the piezoelectric photoelectrocatalytic stability of the photoelectrode but can also effectively accelerate charge interface transfer under piezoelectric polarization, thus effectively improving the photocarrier separation efficiency. This study presents a novel strategy for further practical application of Bi2WO6 photoelectrode piezoelectric photocatalysis.

Graphical abstract: Amorphous CoB layer cooperates with piezoelectric polarization to boost carrier separation of Bi2WO6 for efficient piezo-PEC performance

Supplementary files

Article information

Article type
Paper
Submitted
01 Qas 2023
Accepted
12 Leq 2023
First published
18 Leq 2023

Sustainable Energy Fuels, 2023,7, 4877-4889

Amorphous CoB layer cooperates with piezoelectric polarization to boost carrier separation of Bi2WO6 for efficient piezo-PEC performance

J. You, X. Chen, Z. Liu, Z. Guo and M. Ruan, Sustainable Energy Fuels, 2023, 7, 4877 DOI: 10.1039/D3SE00721A

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