| Literature DB >> 32911929 |
Ling Zhang1,2,3, Hongjun Ji1,2,4, Houbing Huang5, Ning Yi6, Xiaoming Shi5, Senpei Xie2,4, Yaoyin Li2,4, Ziheng Ye4, Pengdong Feng2,4, Tiesong Lin1, Xiangli Liu4, Xuesong Leng1, Mingyu Li1,2,4, Jiaheng Zhang1,2,4, Xing Ma1,2,4, Peng He1, Weiwei Zhao1,2,4, Huanyu Cheng3,6.
Abstract
A soft body area sensor network presents a promising direction in wearable devices to integrate on-body sensors for physiological signal monitoring and flexible printed circuit boards (FPCBs) for signal conditioning/readout and wireless transmission. However, its realization currently relies on various sophisticated fabrication approaches such as lithography or direct printing on a carrier substrate before attaching to the body. Here, we report a universal fabrication scheme to enable printing and room-temperature sintering of the metal nanoparticle on paper/fabric for FPCBs and directly on the human skin for on-body sensors with a novel sintering aid layer. Consisting of polyvinyl alcohol (PVA) paste and nanoadditives in the water, the sintering aid layer reduces the sintering temperature. Together with the significantly decreased surface roughness, it allows for the integration of a submicron-thick conductive pattern with enhanced electromechanical performance. Various on-body sensors integrated with an FPCB to detect health conditions illustrate a system-level example.Entities:
Keywords: body area sensor network; directly printed on-body sensors; flexible printed circuit boards; room-temperature sintering; sintering aid layer
Mesh:
Substances:
Year: 2020 PMID: 32911929 DOI: 10.1021/acsami.0c11479
Source DB: PubMed Journal: ACS Appl Mater Interfaces ISSN: 1944-8244 Impact factor: 9.229