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A reconfigurable piezo-ionotropic polymer membrane for sustainable multi-resonance acoustic sensingopen access

Authors
Ying, Wu BinKim, JoosungKong, ZhengyangYu, ZheBoahen, Elvis K.Li, FenglongChen, ChaoTian, YingKim, JihongChoi, HanbinLee, Jung-YongZhu, JinKim, Do Hwan
Issue Date
Sep-2025
Publisher
Nature Publishing Group
Keywords
Polyurethan; Membranes, Artificial; Polymers; Polyurethanes; Polymer; Polyurethan; Hearing; Hydrophobicity; Membrane; Sustainability; Article; Basilar Membrane; Frequency Discrimination; Sound Pressure; Vibration; Acoustics; Artificial Membrane; Chemistry; Devices; Diagnosis; Human; Perception Deafness; Sound; Acoustics; Hearing Loss, Sensorineural; Humans; Membranes, Artificial; Polymers; Polyurethanes; Sound; Vibration
Citation
Nature Communications, v.16, no.1, pp 1 - 13
Pages
13
Indexed
SCIE
SCOPUS
Journal Title
Nature Communications
Volume
16
Number
1
Start Page
1
End Page
13
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/209270
DOI
10.1038/s41467-025-63643-4
ISSN
2041-1723
2041-1723
Abstract
Sensorineural hearing loss is the most common form of deafness, typically resulting from the loss of sensory cells on the basilar membrane, which cannot regenerate and thus lose sensitivity to sound vibrations. Here, we report a reconfigurable piezo-ionotropic polymer membrane engineered for biomimetic sustainable multi-resonance acoustic sensing, offering exceptional sensitivity (530 kPa-1) and broadband frequency discrimination (20 Hz to 3300 Hz) while remaining resistant to “dying”. The acoustic sensing capability is driven by an ion hitching-in cage effect intrinsic to the ion gel combined with fluorinated polyurethane. In this platform, the engineered ionotropic polymer stretches under acoustic vibrations, allowing cations to penetrate the widened hard segments and engage in strong ion-dipole interactions (cation···F), thereby restricting ion flux and amplifying impedance changes. Additionally, the sensor’s sustainability is ensured through its self-healing properties and hydrophobic components, which enable effective self-repair in both conventional and aqueous environments without ion leakage, achieving a room-temperature healing speed of 0.3–0.4 μm/min. This sustainable acoustic sensing technology enables the devices to reliably identify specific sounds in everyday environments (e.g., human voices, piano notes), demonstrating their potential application as artificial basilar membranes.
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