Phosphorous-Doped High-Entropy Oxides Enabling Full Spectrum Utilization of BiVO4 Photoanodes for Efficient Water Oxidation

Shuaipeng Wang; Hao Yuan; Jiayue Feng; Liangcheng Xu; Mengxuan Guo; Wei Huang; Songcan Wang

doi:10.1002/adfm.202512757

Phosphorous-Doped High-Entropy Oxides Enabling Full Spectrum Utilization of BiVO₄ Photoanodes for Efficient Water Oxidation

Shuaipeng Wang
, Hao Yuan
, Jiayue Feng
, Liangcheng Xu
, Mengxuan Guo
, Wei Huang
, Songcan Wang

柔性电子研究院

Northwestern Polytechnical University Xian

科研成果: 期刊稿件 › 文章 › 同行评审

22 引用（Scopus）

摘要

High-performance BiVO₄ photoanodes generally requires elaborate modification on both bulk and surfaces, which inevitably increases the complexity of photoanode design. Herein, a phosphorus-doped high-entropy oxide composite (P-HEO) is decorated on a BiVO₄ photoanode (denoted as PHBVO), which achieves broadband solar absorption (86% in 300–2500 nm vs 31% for pristine BiVO₄) and delivers a photocurrent density of 6.36 mA cm⁻² at 1.23 V_RHE, representing a fourfold enhancement compared to pristine BiVO₄ photoanodes. Systematical studies reveal that lattice distortion in P-HEOs induces band structure reconstruction and oxygen vacancy formation, while interfacial P─O coupling promotes d-p orbital hybridization, reducing the oxygen evolution reaction overpotential. Moreover, the photothermal effect of P-HEOs suppresses carrier recombination, enhancing electron mobility by 2.6-fold. PHBVO demonstrates stability exceeding 160 h under continuous AM 1.5 G illumination, which is attributed to a robust high-entropy oxide interface. This work provides a proof-of-concept for the design of efficient photoanodes through surface modification simultaneously achieving the enhancement in light harvesting, carrier transport and surface catalytic activity.

源语言	英语
文章编号	e12757
期刊	Advanced Functional Materials
卷	36
期	2
DOI	https://doi.org/10.1002/adfm.202512757
出版状态	已出版 - 5 1月 2026

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title = "Phosphorous-Doped High-Entropy Oxides Enabling Full Spectrum Utilization of BiVO4 Photoanodes for Efficient Water Oxidation",

abstract = "High-performance BiVO4 photoanodes generally requires elaborate modification on both bulk and surfaces, which inevitably increases the complexity of photoanode design. Herein, a phosphorus-doped high-entropy oxide composite (P-HEO) is decorated on a BiVO4 photoanode (denoted as PHBVO), which achieves broadband solar absorption (86\% in 300–2500 nm vs 31\% for pristine BiVO4) and delivers a photocurrent density of 6.36 mA cm−2 at 1.23 VRHE, representing a fourfold enhancement compared to pristine BiVO4 photoanodes. Systematical studies reveal that lattice distortion in P-HEOs induces band structure reconstruction and oxygen vacancy formation, while interfacial P─O coupling promotes d-p orbital hybridization, reducing the oxygen evolution reaction overpotential. Moreover, the photothermal effect of P-HEOs suppresses carrier recombination, enhancing electron mobility by 2.6-fold. PHBVO demonstrates stability exceeding 160 h under continuous AM 1.5 G illumination, which is attributed to a robust high-entropy oxide interface. This work provides a proof-of-concept for the design of efficient photoanodes through surface modification simultaneously achieving the enhancement in light harvesting, carrier transport and surface catalytic activity.",

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AU - Feng, Jiayue

AU - Xu, Liangcheng

AU - Guo, Mengxuan

AU - Huang, Wei

AU - Wang, Songcan

PY - 2026/1/5

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N2 - High-performance BiVO4 photoanodes generally requires elaborate modification on both bulk and surfaces, which inevitably increases the complexity of photoanode design. Herein, a phosphorus-doped high-entropy oxide composite (P-HEO) is decorated on a BiVO4 photoanode (denoted as PHBVO), which achieves broadband solar absorption (86% in 300–2500 nm vs 31% for pristine BiVO4) and delivers a photocurrent density of 6.36 mA cm−2 at 1.23 VRHE, representing a fourfold enhancement compared to pristine BiVO4 photoanodes. Systematical studies reveal that lattice distortion in P-HEOs induces band structure reconstruction and oxygen vacancy formation, while interfacial P─O coupling promotes d-p orbital hybridization, reducing the oxygen evolution reaction overpotential. Moreover, the photothermal effect of P-HEOs suppresses carrier recombination, enhancing electron mobility by 2.6-fold. PHBVO demonstrates stability exceeding 160 h under continuous AM 1.5 G illumination, which is attributed to a robust high-entropy oxide interface. This work provides a proof-of-concept for the design of efficient photoanodes through surface modification simultaneously achieving the enhancement in light harvesting, carrier transport and surface catalytic activity.

AB - High-performance BiVO4 photoanodes generally requires elaborate modification on both bulk and surfaces, which inevitably increases the complexity of photoanode design. Herein, a phosphorus-doped high-entropy oxide composite (P-HEO) is decorated on a BiVO4 photoanode (denoted as PHBVO), which achieves broadband solar absorption (86% in 300–2500 nm vs 31% for pristine BiVO4) and delivers a photocurrent density of 6.36 mA cm−2 at 1.23 VRHE, representing a fourfold enhancement compared to pristine BiVO4 photoanodes. Systematical studies reveal that lattice distortion in P-HEOs induces band structure reconstruction and oxygen vacancy formation, while interfacial P─O coupling promotes d-p orbital hybridization, reducing the oxygen evolution reaction overpotential. Moreover, the photothermal effect of P-HEOs suppresses carrier recombination, enhancing electron mobility by 2.6-fold. PHBVO demonstrates stability exceeding 160 h under continuous AM 1.5 G illumination, which is attributed to a robust high-entropy oxide interface. This work provides a proof-of-concept for the design of efficient photoanodes through surface modification simultaneously achieving the enhancement in light harvesting, carrier transport and surface catalytic activity.

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Phosphorous-Doped High-Entropy Oxides Enabling Full Spectrum Utilization of BiVO4 Photoanodes for Efficient Water Oxidation

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Phosphorous-Doped High-Entropy Oxides Enabling Full Spectrum Utilization of BiVO₄ Photoanodes for Efficient Water Oxidation