A highly conductive, robust, self-healable, and thermally responsive liquid metal-based hydrogel for reversible electrical switches

This study introduces a thermally responsive smart hydrogel with enhanced electrical properties achieved through volume switching. This advancement was realized by incorporating multiscale liquid metal particles (LMPs) into the PNIPAM hydrogel during polymerization, using their inherent elasticity a...

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Bibliographic Details
Published in:Journal of materials chemistry. B, Materials for biology and medicine Materials for biology and medicine, 2024-05, Vol.12 (21), p.5238-5247
Main Authors: Lee, Joo Hyung, Hyun, Ji Eun, Kim, Jongbeom, Yang, Jungin, Zhang, Huanan, Ahn, Hyunchul, Lee, Sohee, Kim, Jung Han, Lim, Taehwan
Format: Article
Language:English
Subjects:
Biocompatibility
Compression
Conductivity
Electrical properties
Human tissues
Hydrogels
Liquid metals
Mechanical properties
Metal particles
Nucleation
Polymerization
Robustness (mathematics)
Switching
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Summary:This study introduces a thermally responsive smart hydrogel with enhanced electrical properties achieved through volume switching. This advancement was realized by incorporating multiscale liquid metal particles (LMPs) into the PNIPAM hydrogel during polymerization, using their inherent elasticity and conductivity when deswelled. Unlike traditional conductive additives, LMPs endow the PNIPAM hydrogel with a remarkably consistent volume switching ratio, significantly enhancing electrical switching. This is attributed to the minimal nucleation effect of LMPs during polymerization and their liquid-like behavior, like vacancies in the polymeric hydrogel under compression. The PNIPAM/LMP hydrogel exhibits the highest electrical switching, with an unprecedented switch of 6.1 orders of magnitude. Even after repeated swelling/deswelling cycles that merge some LMPs and increase the conductivity when swelled, the hydrogel consistently maintains an electrical switch exceeding 4.5 orders of magnitude, which is still the highest record to date. Comprehensive measurements reveal that the hydrogel possesses robust mechanical properties, a tissue-like compression modulus, biocompatibility, and self-healing capabilities. These features make the PNIPAM/LMP hydrogel an ideal candidate for long-term implantable bioelectronics, offering a solution to the mechanical mismatch with dynamic human tissues. A PNIPAM/LMPs hydrogel exhibits the highest electrical switching, with an unprecedented switch of 6.1 orders of magnitude. The hydrogel also possesses robust mechanical properties, a tissue-like compression modulus and self-healing capabilities.
ISSN:2050-750X
2050-7518
DOI:10.1039/d4tb00209a