A Nanonewton-scale Biomimetic Mechanosensor

Overview

Journal Microsyst Nanoeng

Date 2023 Jul 13

PMID 37440869

Authors

Chi Zhang

Mengxi Wu

Ming Li

Lixuan Che

Zhiguang Tan

Di Guo

Zhan Kang

Shuye Cao

Siqi Zhang

Yu Sui

Jining Sun

Liding Wang

Junshan Liu

Affiliations

Soon will be listed here.

Abstract

Biomimetic mechanosensors have profound implications for various areas, including health care, prosthetics, human‒machine interfaces, and robotics. As one of the most important parameters, the sensitivity of mechanosensors is intrinsically determined by the detection resolution to mechanical force. In this manuscript, we expand the force detection resolution of current biomimetic mechanosensors from the micronewton to nanonewton scale. We develop a nanocrack-based electronic whisker-type mechanosensor that has a detection resolution of 72.2 nN. We achieve the perception of subtle mechanical stimuli, such as tiny objects and airflow, and the recognition of surface morphology down to a 30 nm height, which is the finest resolution ever reported in biomimetic mechanosensors. More importantly, we explore the use of this mechanosensor in wearable devices for sensing gravity field orientation with respect to the body, which has not been previously achieved by these types of sensors. We develop a wearable smart system for sensing the body's posture and movements, which can be used for remote monitoring of falls in elderly people. In summary, the proposed device offers great advantages for not only improving sensing ability but also expanding functions and thus can be used in many fields not currently served by mechanosensors.

Citing Articles

Recent Advances in Biomimetics for the Development of Bio-Inspired Prosthetic Limbs.

Varaganti P, Seo S Biomimetics (Basel). 2024; 9(5).

PMID: 38786483 PMC: 11118077. DOI: 10.3390/biomimetics9050273.

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