A self-protective, reproducible textile sensor with high performance towards human–machine interactions

Abstract: A self-protective, reproducible electronic textile with desirable superlyophobicity, mechanical durability and high-sensitive performance for human-machine interaction.

“…(B) Temperature management, 10 Copyright © 2020, American Chemical Society. (C) self‐protection, 11 reproduced from Ref. 10 with permission from The Royal Society of Chemistry.…”

“…A smart wearable sensor system should have high performance, environmental stability, and mechanical stability under severe wear or washing conditions. Zhang et al 11 produced a self‐protective super hydrophobic FCPC (Figure 3C), which can capture deformation normally even after being washed many times. Wearable strain sensors based on FCPCs with self‐protective capability can effectively lower production and maintenance costs, demonstrating attractive applications in healthcare and man−machine exchange.…”

Flexible conductive polymer composites for smart wearable strain sensors

“…(B) Temperature management, 10 Copyright © 2020, American Chemical Society. (C) self‐protection, 11 reproduced from Ref. 10 with permission from The Royal Society of Chemistry.…”

“…A smart wearable sensor system should have high performance, environmental stability, and mechanical stability under severe wear or washing conditions. Zhang et al 11 produced a self‐protective super hydrophobic FCPC (Figure 3C), which can capture deformation normally even after being washed many times. Wearable strain sensors based on FCPCs with self‐protective capability can effectively lower production and maintenance costs, demonstrating attractive applications in healthcare and man−machine exchange.…”

Flexible conductive polymer composites for smart wearable strain sensors

“…During the process of dopamine (DA) oxidation, GO was reduced by PDA and dispersed into the hydrogel network to form an electrical pathway to achieve the purpose of signal transduction. Zhang et al [26] achieved the effec-tive combination of a carbon tube/graphene two-dimensional (2D) film with elastomers such as polydimethylsiloxane (PDMS)/Ecoflex; they endowed the device with multiple features, including ultra-high sensitivity, wide detection range, low detection limit and selfadhesion, and made a preliminary attempt at the largescale production of the device. Peng et al [27] reported on an ultra-tensile hydrogel sensor of liquid metal (LM) filler, that is, a hydrogel sensitive to ultra-tensile force using LM as soft filler in the hydrophilic polymer network.…”

Facile preparation and high performance of wearable strain sensors based on ionically cross-linked composite hydrogels

“…Human-machine interfaces (HMIs), a frontier technology in electronic systems, [1][2][3][4][5][6][7][8] have great potentials in developing personal portable electronics and the Internet of Things (IoT) with high integrity and conformal fashion. [9][10][11][12] However, there are considerable gaps to achieve highly flexible units that can conformally fit to the curved substrate for gesture recognition and pressure sensing. The recent development of flexible and stretchable sensors has opened a new window to achieve highperformance wearable HMIs.…”

Ultraelastic Yarns from Curcumin‐Assisted ELD toward Wearable Human–Machine Interface Textiles