Self-sensing piezoelectric Bi2WO6 electrode for in-situ monitoring interfacial acoustic cavitation

Ruowen Zhao; Nanxuan Xu; Jianyuan Wang; Fang Chen; Wei Zhai

doi:10.1016/j.sna.2026.117613

Self-sensing piezoelectric Bi₂WO₆ electrode for in-situ monitoring interfacial acoustic cavitation

Ruowen Zhao
, Nanxuan Xu
, Jianyuan Wang
, Fang Chen
, Wei Zhai

物理科学与技术学院

Northwestern Polytechnical University Xian

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

To tackle the critical challenge of in-situ monitoring for acoustic cavitation intensity at the liquid-solid interface in sonochemical reactions, a self-sensing electrode based on piezoelectric nanosheet arrays was developed. Utilizing Bi₂WO₆ (BWO) as a model piezoelectric material, the self-sensing detection electrode (BWO SSDE) incorporates a sandwiched layered structure: a functional BWO nanosheet/FTO substrate layer, filled with a flexible insulating elastomer for efficient mechanical-to-electrical conversion while preventing electron leakage, capped by a thin Ag film electrode to collect electrical signals. High-resolution sound pressure spectrograms were acquired during ultrasonication through advanced signal processing and calibration algorithms. This enabled systematic analysis of sound pressure level (SPL) variation characteristics at fundamental and harmonic frequencies across diverse ultrasonic conditions. Validation confirmed that the third-harmonic frequency SPL (SPL_60 kHz) stably quantifies interfacial acoustic cavitation intensity, achieving a detection sensitivity of 0.2 dB/μm. This system was further extended to monitor sonochemical induced self-assembly reactions of organic molecules, in-situ tracking the dynamic correlation between the evolution of polyphenol aggregation (PAs) structures and interfacial SPL under ultrasonication. The proposed piezoelectric-based acoustic self-sensing system not only provides a new method for precise and real-time monitoring of acoustic cavitation intensity at liquid-solid interface but also establishes a new paradigm for constructing sensing devices using diverse piezoelectric materials.

源语言	英语
文章编号	117613
期刊	Sensors and Actuators, A: Physical
卷	402
DOI	https://doi.org/10.1016/j.sna.2026.117613
出版状态	已出版 - 1 5月 2026

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10.1016/j.sna.2026.117613

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title = "Self-sensing piezoelectric Bi2WO6 electrode for in-situ monitoring interfacial acoustic cavitation",

abstract = "To tackle the critical challenge of in-situ monitoring for acoustic cavitation intensity at the liquid-solid interface in sonochemical reactions, a self-sensing electrode based on piezoelectric nanosheet arrays was developed. Utilizing Bi2WO6 (BWO) as a model piezoelectric material, the self-sensing detection electrode (BWO SSDE) incorporates a sandwiched layered structure: a functional BWO nanosheet/FTO substrate layer, filled with a flexible insulating elastomer for efficient mechanical-to-electrical conversion while preventing electron leakage, capped by a thin Ag film electrode to collect electrical signals. High-resolution sound pressure spectrograms were acquired during ultrasonication through advanced signal processing and calibration algorithms. This enabled systematic analysis of sound pressure level (SPL) variation characteristics at fundamental and harmonic frequencies across diverse ultrasonic conditions. Validation confirmed that the third-harmonic frequency SPL (SPL60 kHz) stably quantifies interfacial acoustic cavitation intensity, achieving a detection sensitivity of 0.2 dB/μm. This system was further extended to monitor sonochemical induced self-assembly reactions of organic molecules, in-situ tracking the dynamic correlation between the evolution of polyphenol aggregation (PAs) structures and interfacial SPL under ultrasonication. The proposed piezoelectric-based acoustic self-sensing system not only provides a new method for precise and real-time monitoring of acoustic cavitation intensity at liquid-solid interface but also establishes a new paradigm for constructing sensing devices using diverse piezoelectric materials.",

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author = "Ruowen Zhao and Nanxuan Xu and Jianyuan Wang and Fang Chen and Wei Zhai",

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AU - Zhao, Ruowen

AU - Xu, Nanxuan

AU - Wang, Jianyuan

AU - Chen, Fang

AU - Zhai, Wei

PY - 2026/5/1

Y1 - 2026/5/1

N2 - To tackle the critical challenge of in-situ monitoring for acoustic cavitation intensity at the liquid-solid interface in sonochemical reactions, a self-sensing electrode based on piezoelectric nanosheet arrays was developed. Utilizing Bi2WO6 (BWO) as a model piezoelectric material, the self-sensing detection electrode (BWO SSDE) incorporates a sandwiched layered structure: a functional BWO nanosheet/FTO substrate layer, filled with a flexible insulating elastomer for efficient mechanical-to-electrical conversion while preventing electron leakage, capped by a thin Ag film electrode to collect electrical signals. High-resolution sound pressure spectrograms were acquired during ultrasonication through advanced signal processing and calibration algorithms. This enabled systematic analysis of sound pressure level (SPL) variation characteristics at fundamental and harmonic frequencies across diverse ultrasonic conditions. Validation confirmed that the third-harmonic frequency SPL (SPL60 kHz) stably quantifies interfacial acoustic cavitation intensity, achieving a detection sensitivity of 0.2 dB/μm. This system was further extended to monitor sonochemical induced self-assembly reactions of organic molecules, in-situ tracking the dynamic correlation between the evolution of polyphenol aggregation (PAs) structures and interfacial SPL under ultrasonication. The proposed piezoelectric-based acoustic self-sensing system not only provides a new method for precise and real-time monitoring of acoustic cavitation intensity at liquid-solid interface but also establishes a new paradigm for constructing sensing devices using diverse piezoelectric materials.

AB - To tackle the critical challenge of in-situ monitoring for acoustic cavitation intensity at the liquid-solid interface in sonochemical reactions, a self-sensing electrode based on piezoelectric nanosheet arrays was developed. Utilizing Bi2WO6 (BWO) as a model piezoelectric material, the self-sensing detection electrode (BWO SSDE) incorporates a sandwiched layered structure: a functional BWO nanosheet/FTO substrate layer, filled with a flexible insulating elastomer for efficient mechanical-to-electrical conversion while preventing electron leakage, capped by a thin Ag film electrode to collect electrical signals. High-resolution sound pressure spectrograms were acquired during ultrasonication through advanced signal processing and calibration algorithms. This enabled systematic analysis of sound pressure level (SPL) variation characteristics at fundamental and harmonic frequencies across diverse ultrasonic conditions. Validation confirmed that the third-harmonic frequency SPL (SPL60 kHz) stably quantifies interfacial acoustic cavitation intensity, achieving a detection sensitivity of 0.2 dB/μm. This system was further extended to monitor sonochemical induced self-assembly reactions of organic molecules, in-situ tracking the dynamic correlation between the evolution of polyphenol aggregation (PAs) structures and interfacial SPL under ultrasonication. The proposed piezoelectric-based acoustic self-sensing system not only provides a new method for precise and real-time monitoring of acoustic cavitation intensity at liquid-solid interface but also establishes a new paradigm for constructing sensing devices using diverse piezoelectric materials.

KW - Acoustic cavitation

KW - BiWO

KW - Piezoelectric

KW - Self-sensing detection

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DO - 10.1016/j.sna.2026.117613

M3 - 文章

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SN - 0924-4247

VL - 402

JO - Sensors and Actuators, A: Physical

JF - Sensors and Actuators, A: Physical

M1 - 117613

ER -

Self-sensing piezoelectric Bi2WO6 electrode for in-situ monitoring interfacial acoustic cavitation

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Self-sensing piezoelectric Bi₂WO₆ electrode for in-situ monitoring interfacial acoustic cavitation