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Main Authors: de Oliveira, Edson Rafael Cardozo, Grosman, Gastón, Xiang, Chushuang, Zuarez-Chamba, Michael, Vensaus, Priscila, Harouri, Abdelmounaim, Boissiere, Cédric, Soler-Illia, Galo J. A. A., Lanzillotti-Kimura, Norberto Daniel
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.19688
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author de Oliveira, Edson Rafael Cardozo
Grosman, Gastón
Xiang, Chushuang
Zuarez-Chamba, Michael
Vensaus, Priscila
Harouri, Abdelmounaim
Boissiere, Cédric
Soler-Illia, Galo J. A. A.
Lanzillotti-Kimura, Norberto Daniel
author_facet de Oliveira, Edson Rafael Cardozo
Grosman, Gastón
Xiang, Chushuang
Zuarez-Chamba, Michael
Vensaus, Priscila
Harouri, Abdelmounaim
Boissiere, Cédric
Soler-Illia, Galo J. A. A.
Lanzillotti-Kimura, Norberto Daniel
contents The engineering of acoustic phonons in the gigahertz (GHz) range holds significant potential for technological breakthroughs in areas such as data processing, sensing and quantum communication. Novel approaches for nanophononic resonators responsive to external stimuli provide additional control and functionality for these devices. Mesoporous thin films (MTFs) for example, featuring nanoscale ordered pores, support GHz-range acoustic resonances. These materials are sensitive to environmental changes, such as liquid and vapor infiltration, modifying their effective optical and elastic properties. Here, a SiO$_{2}$ MTF-based open-cavity nanoacoustic resonator is presented, in which the MTF forms the topmost layer and is exposed to the environment. Using a transient reflectivity setup, acoustic responses under varying humidity conditions are investigated. A pronounced shift in acoustic resonance frequency with changes in relative humidity is observed for the first time, demonstrating a simple way to tune hypersound confinement. In addition, resonators with varying pore sizes and thicknesses are compared, revealing that resonance frequencies are primarily influenced by material properties and film thickness, rather than pore size. The proposed open-cavity resonator design provides a versatile platform for future studies on the mechanical response of MTFs to liquid and vapor infiltration, opening the gate to environment-responsive hypersound devices.
format Preprint
id arxiv_https___arxiv_org_abs_2507_19688
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Towards Environmentally Responsive Hypersound Materials
de Oliveira, Edson Rafael Cardozo
Grosman, Gastón
Xiang, Chushuang
Zuarez-Chamba, Michael
Vensaus, Priscila
Harouri, Abdelmounaim
Boissiere, Cédric
Soler-Illia, Galo J. A. A.
Lanzillotti-Kimura, Norberto Daniel
Mesoscale and Nanoscale Physics
The engineering of acoustic phonons in the gigahertz (GHz) range holds significant potential for technological breakthroughs in areas such as data processing, sensing and quantum communication. Novel approaches for nanophononic resonators responsive to external stimuli provide additional control and functionality for these devices. Mesoporous thin films (MTFs) for example, featuring nanoscale ordered pores, support GHz-range acoustic resonances. These materials are sensitive to environmental changes, such as liquid and vapor infiltration, modifying their effective optical and elastic properties. Here, a SiO$_{2}$ MTF-based open-cavity nanoacoustic resonator is presented, in which the MTF forms the topmost layer and is exposed to the environment. Using a transient reflectivity setup, acoustic responses under varying humidity conditions are investigated. A pronounced shift in acoustic resonance frequency with changes in relative humidity is observed for the first time, demonstrating a simple way to tune hypersound confinement. In addition, resonators with varying pore sizes and thicknesses are compared, revealing that resonance frequencies are primarily influenced by material properties and film thickness, rather than pore size. The proposed open-cavity resonator design provides a versatile platform for future studies on the mechanical response of MTFs to liquid and vapor infiltration, opening the gate to environment-responsive hypersound devices.
title Towards Environmentally Responsive Hypersound Materials
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2507.19688