Nonpatterned Soft Piezoresistive Films with Filamentous Conduction Paths for Mimicking Multiple-Resolution Receptors of Human Skin

Authors
Kim, HanulChoi, SeongdaeLee, ByeongmoonSeo, JiseokLee, SeunghwanYoon, JinsuHong, Yongtaek
Issue Date
2022-12
Publisher
American Chemical Society
Citation
ACS Applied Materials & Interfaces, v.14, no.49, pp.55088 - 55097
Abstract
Soft pressure sensors play key roles as input devices of electronic skin (E-skin) to imitate real human skin. For efficient data acquisition according to stimulus types such as detailed pressure images or macroscopic strength of stimuli, soft pressure sensors can have variable spatial resolution, just like the uneven spatial distribution of pressure-sensing receptors on the human body. However, previous methods on soft pressure sensors cannot achieve such tunability of spatial resolution because their sensor materials and read-out electrodes need to be elaborately patterned for a specific sensor density. Here, we report a universal soft pressure-sensitive platform based on anisotropically self-assembled ferromagnetic particles embedded in elastomer matrices whose spatial resolution can be facilely tuned. Various spatial densities of pressure-sensing receptors of human body parts can be implemented by simply sandwiching the film between soft electrodes with different pitches. Since the anisotropically aligned nickel particles form independent filamentous conductive paths, the pressure sensors show spatial sensing ability without crosstalk, whose spatial resolution up to 100 dpi can be achieved from a single platform. The sensor array shows a wide dynamic range capable of detecting various pressure levels, such as liquid drops (similar to 30 Pa) and plantar (similar to 300 kPa) pressures. Our universal soft pressure -sensing platform would be a key enabling technology for actually imitating the receptor systems of human skin in robot and biomedical applications.
Keywords
ELECTRONIC SKIN; HUMAN HAND; SENSORS; TACTILE; COMPOSITE; PRESSURE; DISCRIMINATION; FRAGMENTATION; POLYETHYLENE; DENSITIES; pressure sensor; electronic skin; sensor matrix; nonpatterned; multiple resolution; piezoresistive
ISSN
1944-8244
URI
https://pubs.kist.re.kr/handle/201004/114219
DOI
10.1021/acsami.2c16929
Appears in Collections:
KIST Article > 2022
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