Issue 9, 2016

3D Bi2S3 salix leaf-like nanosheet/TiO2 nanorod branched heterostructure arrays for improving photoelectrochemical properties

Abstract

We firstly fabricated a peculiar 3D structure of Bi2S3 salix leaf-like nanosheet/TiO2 nanorod branched heterostructure arrays by a convenient hydrothermal method and discussed their mechanism of improving photoelectrochemical cell (PEC) properties. The salix leaf-like Bi2S3 nanosheets (NSs) were grown on TiO2 nanorod arrays through controlling the molar ratio of EDTA-Na2/Bi3+ and the reaction time. The morphology, crystal structure, microstructure and optical performance of the 3D Bi2S3 NS/TiO2 NRs at different reaction times were investigated. The results show that the branched heterostructure of 3D Bi2S3 NS/TiO2 NR arrays exhibits enhanced photocurrent density and optical absorption, which were attributed to the larger Bi2S3 surface area, as well as a direct electron path within the salix leaf-like Bi2S3 NS and TiO2 NR heterojunctions, resulting from more excitation sites of incident light. The photocurrent density of the 3D Bi2S3 NS/TiO2 NR arrays was almost 9 times greater than that of pristine TiO2 without a branching structure. The results of the present work demonstrate that fabrication of the branched Bi2S3 NS/TiO2 NR heterogeneous structure is a significant fabrication technology with great promise in PECs.

Graphical abstract: 3D Bi2S3 salix leaf-like nanosheet/TiO2 nanorod branched heterostructure arrays for improving photoelectrochemical properties

Article information

Article type
Paper
Submitted
19 Nov 2015
Accepted
20 Jan 2016
First published
21 Jan 2016

CrystEngComm, 2016,18, 1577-1584

3D Bi2S3 salix leaf-like nanosheet/TiO2 nanorod branched heterostructure arrays for improving photoelectrochemical properties

Y. Wan, M. Han, L. Yu, G. Yi and J. Jia, CrystEngComm, 2016, 18, 1577 DOI: 10.1039/C5CE02252E

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