Kunigunde Cherenack scite author profile

Smart textiles research represents a new model for generating creative and novel solutions for integrating electronics into unusual environments and will result in new discoveries that push the boundaries of science forward. A key driver for smart textiles research is the fact that both textile and electronics fabrication processes are capable of functionalizing large-area surfaces at very high speeds. In this article we review the history of smart textiles development, introducing the main trends and technological challenges faced in this field. Then, we identify key challenges that are the focus of ongoing research. We then proceed to discuss fundamentals of smart textiles: textile fabrication methods and textile interconnect lines, textile sensor, and output device components and integration of commercial components into textile architectures. Next we discuss representative smart textile systems and finally provide our outlook over the field and a prediction for the future. V

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Woven Electronic Fibers with Sensing and Display Functions for Smart Textiles

Cherenack

et al. 2010

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The Effects of Mechanical Bending and Illumination on the Performance of Flexible IGZO TFTs

Münzenrieder

Cherenack

Tröster

2011

IEEE Trans. Electron Devices

164

133

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A textile integrated sensor system for monitoring humidity and temperature

Kinkeldei

Zysset

Cherenack

et al. 2011

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Locally Reinforced Polymer-Based Composites for Elastic Electronics

Erb¹,

Cherenack

Stahel³

et al. 2012

ACS Appl. Mater. Interfaces

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A promising approach to fabricating elastic electronic systems involves processing thin film circuits directly on the elastic substrate by standard photolithography. Thin film devices are generally placed onto stiffer islands on the substrate surface to protect devices from excessive strain while still achieving a globally highly deformable system. Here we report a new method to achieve island architectures by locally reinforcing polymeric substrates at the macro- and microscale using magnetically responsive anisotropic microparticles. We demonstrate that the resulting particle-reinforced elastic substrates can be made smooth enough for the patterning and successful operation of thin film transistors with transfer characteristics comparable to state-of-the-art devices.

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