Halogen Atom (Cl, Br, and I) Doping Effects on the Electronic Character and OER Performance of BiVO4 as a Photoanode Nanomaterial for Solar Water Splitting: A Theoretical Study.

IF 3.9 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Langmuir Pub Date : 2025-05-20 DOI:10.1021/acs.langmuir.5c00532

Xinxia Li,Yiteng Zhang,Zhou Fang,Xin Feng,Ya Xu,Huifang Li

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Abstract

Halogen elements, as common nonmetal dopants, have attracted significant attention for their potential in creating highly active photocatalysts. To improve the electronic property of BiVO4, a highly promising photoanode nanomaterial for solar water splitting, the halogen atom (Cl, Br, and I) doping strategy and underlying modification mechanisms were explored in detail by the first-principles calculations here. Formation energies confirmed that halogen doping at the O sites of BiVO4 is energetically favorable and can be realized experimentally. The conduction band minimum (CBM) energy level is stabilized and even shifted into the occupied electron states, while the valence band maximum (VBM) energy level is increased for BiVO4 upon halogen atom doping with a trend: I > Br > Cl. Furthermore, the n-type electron-donating behavior becomes increasingly significant with higher dopant mass concentrations, which is attributed to the lower electronegativity of introduced halogen atoms compared to that of the substituted O atoms. Moreover, doping with Cl, Br, or I atoms induces strong spin polarization and effectively suppresses the recombination of photogenerated electron-hole pairs in BiVO4. Furthermore, H2O adsorption energy and Gibbs free energy change (ΔG) results for each fundamental stage confirmed that the oxygen evolution reaction (OER) process is favored by such an n-type doping method. All of these results proved that halogen atom (Cl, Br, and I) doping is a reliable strategy to improve photoelectrical properties, consequently boosting the photocatalytic performance of BiVO4 through modifications to its electronic structure.

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卤素原子（Cl， Br和I）掺杂对BiVO4作为太阳能水分解光阳极材料的电子特性和OER性能的影响：理论研究

卤素元素作为一种常见的非金属掺杂剂，因其在制备高活性光催化剂方面的潜力而备受关注。为了提高BiVO4（一种非常有前途的太阳能水分解光阳极纳米材料）的电子性能，本文通过第一性原理计算详细探讨了卤素原子（Cl， Br和I）的掺杂策略和潜在的修饰机制。形成能证实了卤素掺杂在BiVO4的O位上是有利的，可以通过实验实现。卤素原子掺杂后，BiVO4的导带最小能级（CBM）稳定，甚至转移到已占据电子态，而价带最大能级（VBM）呈I > Br > Cl的趋势增加。此外，随着掺杂质量浓度的增加，n型给电子行为变得越来越显著，这是由于引入的卤素原子的电负性比取代的O原子的电负性更低。此外，掺杂Cl、Br或I原子可诱导强自旋极化，有效抑制BiVO4中光生电子-空穴对的复合。此外，各基本阶段的H2O吸附能和Gibbs自由能变化（ΔG）结果证实了这种n型掺杂方法有利于析氧反应（OER）过程。这些结果都证明了卤素原子（Cl， Br和I）掺杂是改善BiVO4光电性能的可靠策略，从而通过改变其电子结构来提高其光催化性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Langmuir 化学-材料科学：综合

CiteScore

6.50

自引率

10.30%

发文量

1464

审稿时长

2.1 months

期刊介绍： Langmuir is an interdisciplinary journal publishing articles in the following subject categories: Colloids: surfactants and self-assembly, dispersions, emulsions, foams Interfaces: adsorption, reactions, films, forces Biological Interfaces: biocolloids, biomolecular and biomimetic materials Materials: nano- and mesostructured materials, polymers, gels, liquid crystals Electrochemistry: interfacial charge transfer, charge transport, electrocatalysis, electrokinetic phenomena, bioelectrochemistry Devices and Applications: sensors, fluidics, patterning, catalysis, photonic crystals However, when high-impact, original work is submitted that does not fit within the above categories, decisions to accept or decline such papers will be based on one criteria: What Would Irving Do? Langmuir ranks #2 in citations out of 136 journals in the category of Physical Chemistry with 113,157 total citations. The journal received an Impact Factor of 4.384*. This journal is also indexed in the categories of Materials Science (ranked #1) and Multidisciplinary Chemistry (ranked #5).