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

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 an...

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Veröffentlicht in:Materials horizons 2021-08, Vol.8 (9), p.2513-2519
Hauptverfasser: Wan, Kening, Liu, Yi, Santagiuliana, Giovanni, Barandun, Giandrin, Taroni Junior, Prospero, Güder, Firat, Bastiaansen, Cees WM, Baxendale, Mark, Fenwick, Oliver, Papageorgiou, Dimitrios G, Krause, Steffi, Zhang, Han, Bilotti, Emiliano
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Sprache:eng
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Zusammenfassung: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 × 10 5 , 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 Δ T ∼ 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. A step towards functionally-integrated and autonomous systems, where functions such as sensing and energy storage/harvesting should ideally be carried out by a single material, while retaining its ability to withstand large elastic deformations.
ISSN:2051-6347
2051-6355
DOI:10.1039/d1mh00908g