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Abstract
Electronic skins (e-skins) are desired to perceive both the intensity and spatial distribution of applied pressures. Despite the continuous progress in the design of high-performance individual pressure sensors, the acquisition of the locational information of pressures still mostly relies on the preparation of high-density sensor matrixes within e-skins, which dramatically increases device complexity and hinders the straightforward human-machine interaction. In recent years, the integration of optical pressure visualization units within e-skins has been raised as an alternative strategy for obtaining pressure distribution. By utilizing pressure-induced light emission and color change, the applied pressure could be visualized directly through the distinct optical signals, eliminating the necessity of additional data processing and display modules. In this perspective, the main strategies to achieve pressure visualization in e-skins are introduced, including their mechanism, device layout, materials, and applications. The challenges and prospects of this emerging field are also discussed.
Keywords
E-skin
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pressure visualization
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mechanoluminescence
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piezophototronics
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electrochromism
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structural color
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Xingyi Li, Zhirou Wu, Zetong Chen, Jidong Shi.
From touching to seeing: visualized pressure sensing in electronic skins.
Soft Science, 2025, 5(2): 16 DOI:10.20517/ss.2024.76
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