Localized Oxidative Catalytic Reactions Triggered by Cavitation Bubbles Confinement on Copper Oxide Microstructured Particles.

Valarmathi Mahendran; Quang Thang Trinh; Xie Zhangyue; Umesh Jonnalagadda; Tim Gould; Nam Trung Nguyen; James Kwan; Tej S. Choksi; Wen Liu; Sabine Valange; François Jérôme; Prince Nana Amaniampong

doi:10.1002/anie.202416543

Localized Oxidative Catalytic Reactions Triggered by Cavitation Bubbles Confinement on Copper Oxide Microstructured Particles.

Valarmathi Mahendran, Quang Thang Trinh, Xie Zhangyue, Umesh Jonnalagadda, Tim Gould, Nam Trung Nguyen, James Kwan, Tej S. Choksi, Wen Liu, Sabine Valange, François Jérôme, Prince Nana Amaniampong^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Efficient energy transfer management in catalytic processes is crucial for overcoming activation energy barriers while minimizing costs and CO₂ emissions. We exploit here a concept of CuO particle design with multiple gas-stabilizing sites, engineered to function as cavitation nuclei and catalysts. This concept facilitates the selective and efficient acoustic energy transfer directly to the catalyst surface, avoiding the undesired dissipation of acoustic energy into the bulk solution while demonstrating superior cavitation properties at lower acoustic pressure amplitudes. Utilizing a chemical thermometric approach, we demonstrate that the local temperature on the surface of our CuO particles during cavitation bubble implosions can create an effective equivalent temperature of about 360 °C. This temperature effect facilitates the efficient catalysis of oxidative reactions using an organic pollutant probe molecule. Density functional theory (DFT) calculations were used to assess the decomposition of H₂O₂ and of pollutant probe molecule on CuO (111). Our work represents a significant advance in sonocatalytic systems, promising efficient energy use in catalytic reactions.

Original language	English
Journal	Angewandte Chemie - International Edition
DOIs	https://doi.org/10.1002/anie.202416543
Publication status	Accepted/In press - 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2024 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.

ASJC Scopus Subject Areas

Catalysis
General Chemistry

Keywords

Catalytic cavitation agent
cavitation nucleation
Effective local temperature
Localised heating
Ultrasound irradiation

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10.1002/anie.202416543

Cite this

Mahendran, V., Trinh, Q. T., Zhangyue, X., Jonnalagadda, U., Gould, T., Nguyen, N. T., Kwan, J., Choksi, T. S., Liu, W., Valange, S., Jérôme, F., & Amaniampong, P. N. (Accepted/In press). Localized Oxidative Catalytic Reactions Triggered by Cavitation Bubbles Confinement on Copper Oxide Microstructured Particles. Angewandte Chemie - International Edition. https://doi.org/10.1002/anie.202416543

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doi = "10.1002/anie.202416543",

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AU - Jonnalagadda, Umesh

AU - Gould, Tim

AU - Nguyen, Nam Trung

AU - Kwan, James

AU - Choksi, Tej S.

AU - Liu, Wen

AU - Valange, Sabine

AU - Jérôme, François

AU - Amaniampong, Prince Nana

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N2 - Efficient energy transfer management in catalytic processes is crucial for overcoming activation energy barriers while minimizing costs and CO2 emissions. We exploit here a concept of CuO particle design with multiple gas-stabilizing sites, engineered to function as cavitation nuclei and catalysts. This concept facilitates the selective and efficient acoustic energy transfer directly to the catalyst surface, avoiding the undesired dissipation of acoustic energy into the bulk solution while demonstrating superior cavitation properties at lower acoustic pressure amplitudes. Utilizing a chemical thermometric approach, we demonstrate that the local temperature on the surface of our CuO particles during cavitation bubble implosions can create an effective equivalent temperature of about 360 °C. This temperature effect facilitates the efficient catalysis of oxidative reactions using an organic pollutant probe molecule. Density functional theory (DFT) calculations were used to assess the decomposition of H2O2 and of pollutant probe molecule on CuO (111). Our work represents a significant advance in sonocatalytic systems, promising efficient energy use in catalytic reactions.

AB - Efficient energy transfer management in catalytic processes is crucial for overcoming activation energy barriers while minimizing costs and CO2 emissions. We exploit here a concept of CuO particle design with multiple gas-stabilizing sites, engineered to function as cavitation nuclei and catalysts. This concept facilitates the selective and efficient acoustic energy transfer directly to the catalyst surface, avoiding the undesired dissipation of acoustic energy into the bulk solution while demonstrating superior cavitation properties at lower acoustic pressure amplitudes. Utilizing a chemical thermometric approach, we demonstrate that the local temperature on the surface of our CuO particles during cavitation bubble implosions can create an effective equivalent temperature of about 360 °C. This temperature effect facilitates the efficient catalysis of oxidative reactions using an organic pollutant probe molecule. Density functional theory (DFT) calculations were used to assess the decomposition of H2O2 and of pollutant probe molecule on CuO (111). Our work represents a significant advance in sonocatalytic systems, promising efficient energy use in catalytic reactions.

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KW - Localised heating

KW - Ultrasound irradiation

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Localized Oxidative Catalytic Reactions Triggered by Cavitation Bubbles Confinement on Copper Oxide Microstructured Particles.

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

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