Issue 9, 2021

Self-powered ultrasensitive and highly stretchable temperature–strain sensing composite yarns

Abstract

With the emergence of stretchable/wearable devices, functions, such as sensing, energy storage/harvesting, and electrical conduction, should ideally be carried out by a single material, while retaining its ability to withstand large elastic deformations, to create compact, functionally-integrated and autonomous systems. A new class of trimodal, stretchable yarn-based transducer formed by coating commercially available Lycra® yarns with PEDOT:PSS is presented. The material developed can sense strain (first mode), and temperature (second mode) and can power itself thermoelectrically (third mode), eliminating the need for an external power-supply. The yarns were extensively characterized and obtained an ultrahigh (gauge factor ∼3.6 × 105, at 10–20% strain) and tunable (up to about 2 orders of magnitude) strain sensitivity together with a very high strain-at-break point (up to ∼1000%). These PEDOT:PSS-Lycra yarns also exhibited stable thermoelectric behavior (Seebeck coefficient of 15 μV K−1), which was exploited both for temperature sensing and self-powering (∼0.5 μW, for a 10-couple module at ΔT ∼ 95 K). The produced material has potential to be interfaced with microcontroller-based systems to create internet-enabled, internet-of-things type devices in a variety of form factors.

Graphical abstract: Self-powered ultrasensitive and highly stretchable temperature–strain sensing composite yarns

Supplementary files

Article information

Article type
Communication
Submitted
09 Jun 2021
Accepted
12 Jul 2021
First published
12 Jul 2021
This article is Open Access
Creative Commons BY-NC license

Mater. Horiz., 2021,8, 2513-2519

Self-powered ultrasensitive and highly stretchable temperature–strain sensing composite yarns

K. Wan, Y. Liu, G. Santagiuliana, G. Barandun, P. Taroni Junior, F. Güder, C. W. Bastiaansen, M. Baxendale, O. Fenwick, D. G. Papageorgiou, S. Krause, H. Zhang and E. Bilotti, Mater. Horiz., 2021, 8, 2513 DOI: 10.1039/D1MH00908G

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