Anti-friction Gold-based Stretchable Electronics Enabled by Interfacial Diffusion-induced Cohesion

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Feb 6

PMID 38321072

Authors

Jie Cao

Xusheng Liu

Jie Qiu

Zhifei Yue

Yang Li

Qian Xu

Yan Chen

Jiewen Chen

Hongfei Cheng

Guozhong Xing

Enming Song

Ming Wang

Qi Liu

Ming Liu

Affiliations

Soon will be listed here.

Abstract

Stretchable electronics that prevalently adopt chemically inert metals as sensing layers and interconnect wires have enabled high-fidelity signal acquisition for on-skin applications. However, the weak interfacial interaction between inert metals and elastomers limit the tolerance of the device to external friction interferences. Here, we report an interfacial diffusion-induced cohesion strategy that utilizes hydrophilic polyurethane to wet gold (Au) grains and render them wrapped by strong hydrogen bonding, resulting in a high interfacial binding strength of 1017.6 N/m. By further constructing a nanoscale rough configuration of the polyurethane (RPU), the binding strength of Au-RPU device increases to 1243.4 N/m, which is 100 and 4 times higher than that of conventional polydimethylsiloxane and styrene-ethylene-butylene-styrene-based devices, respectively. The stretchable Au-RPU device can remain good electrical conductivity after 1022 frictions at 130 kPa pressure, and reliably record high-fidelity electrophysiological signals. Furthermore, an anti-friction pressure sensor array is constructed based on Au-RPU interconnect wires, demonstrating a superior mechanical durability for concentrated large pressure acquisition. This chemical modification-free approach of interfacial strengthening for chemically inert metal-based stretchable electronics is promising for three-dimensional integration and on-chip interconnection.

Citing Articles

Facile synthesis of ultratough conductive gels with swelling and freezing resistance for flexible sensor applications.

Lu P, Xu J, Liu S, Fu L, Wu S, Liu Z Sci Rep. 2025; 15(1):7335.

PMID: 40025152 PMC: 11873186. DOI: 10.1038/s41598-025-86541-7.

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