Haptically Quantifying Young's Modulus of Soft Materials Using a Self-Locked Stretchable Strain Sensor

Zequn Cui; Wensong Wang; Lingling Guo; Zhihua Liu; Pingqiang Cai; Yajing Cui; Ting Wang; Changxian Wang; Ming Zhu; Ying Zhou; Wenyan Liu; Yuanjin Zheng; Guoying Deng; Chuanlai Xu; Xiaodong Chen

doi:10.1002/adma.202104078

Haptically Quantifying Young's Modulus of Soft Materials Using a Self-Locked Stretchable Strain Sensor

Zequn Cui, Wensong Wang, Lingling Guo, Zhihua Liu, Pingqiang Cai, Yajing Cui, Ting Wang, Changxian Wang, Ming Zhu, Ying Zhou, Wenyan Liu, Yuanjin Zheng, Guoying Deng^*, Chuanlai Xu^*, Xiaodong Chen^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

61 Citations (Scopus)

Abstract

Simple and rapid Young's modulus measurements of soft materials adaptable to various scenarios are of general significance, and they require miniaturized measurement platforms with easy operation. Despite the advances made in portable and wearable approaches, acquiring and analyzing multiple or complicated signals necessitate tethered bulky components and careful preparation. Here, a new methodology based on a self-locked stretchable strain sensor to haptically quantify Young's modulus of soft materials (kPa–MPa) rapidly is reported. The method demonstrates a fingertip measurement platform, which endows a prosthetic finger with human-comparable haptic behaviors and skills on elasticity sensing without activity constraints. A universal strategy is offered toward ultraconvenient and high-efficient Young's modulus measurements with wide adaptability to various fields for unprecedented applications.

Original language	English
Article number	2104078
Journal	Advanced Materials
Volume	34
Issue number	25
DOIs	https://doi.org/10.1002/adma.202104078
Publication status	Published - Jun 23 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021 Wiley-VCH GmbH.

ASJC Scopus Subject Areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

Keywords

haptics
self-locking
stretchable strain sensors
Young's modulus

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10.1002/adma.202104078

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title = "Haptically Quantifying Young's Modulus of Soft Materials Using a Self-Locked Stretchable Strain Sensor",

abstract = "Simple and rapid Young's modulus measurements of soft materials adaptable to various scenarios are of general significance, and they require miniaturized measurement platforms with easy operation. Despite the advances made in portable and wearable approaches, acquiring and analyzing multiple or complicated signals necessitate tethered bulky components and careful preparation. Here, a new methodology based on a self-locked stretchable strain sensor to haptically quantify Young's modulus of soft materials (kPa–MPa) rapidly is reported. The method demonstrates a fingertip measurement platform, which endows a prosthetic finger with human-comparable haptic behaviors and skills on elasticity sensing without activity constraints. A universal strategy is offered toward ultraconvenient and high-efficient Young's modulus measurements with wide adaptability to various fields for unprecedented applications.",

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doi = "10.1002/adma.202104078",

language = "English",

volume = "34",

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AU - Cui, Zequn

AU - Wang, Wensong

AU - Guo, Lingling

AU - Liu, Zhihua

AU - Cai, Pingqiang

AU - Cui, Yajing

AU - Wang, Ting

AU - Wang, Changxian

AU - Zhu, Ming

AU - Zhou, Ying

AU - Liu, Wenyan

AU - Zheng, Yuanjin

AU - Deng, Guoying

AU - Xu, Chuanlai

AU - Chen, Xiaodong

PY - 2022/6/23

Y1 - 2022/6/23

N2 - Simple and rapid Young's modulus measurements of soft materials adaptable to various scenarios are of general significance, and they require miniaturized measurement platforms with easy operation. Despite the advances made in portable and wearable approaches, acquiring and analyzing multiple or complicated signals necessitate tethered bulky components and careful preparation. Here, a new methodology based on a self-locked stretchable strain sensor to haptically quantify Young's modulus of soft materials (kPa–MPa) rapidly is reported. The method demonstrates a fingertip measurement platform, which endows a prosthetic finger with human-comparable haptic behaviors and skills on elasticity sensing without activity constraints. A universal strategy is offered toward ultraconvenient and high-efficient Young's modulus measurements with wide adaptability to various fields for unprecedented applications.

AB - Simple and rapid Young's modulus measurements of soft materials adaptable to various scenarios are of general significance, and they require miniaturized measurement platforms with easy operation. Despite the advances made in portable and wearable approaches, acquiring and analyzing multiple or complicated signals necessitate tethered bulky components and careful preparation. Here, a new methodology based on a self-locked stretchable strain sensor to haptically quantify Young's modulus of soft materials (kPa–MPa) rapidly is reported. The method demonstrates a fingertip measurement platform, which endows a prosthetic finger with human-comparable haptic behaviors and skills on elasticity sensing without activity constraints. A universal strategy is offered toward ultraconvenient and high-efficient Young's modulus measurements with wide adaptability to various fields for unprecedented applications.

KW - haptics

KW - self-locking

KW - stretchable strain sensors

KW - Young's modulus

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Haptically Quantifying Young's Modulus of Soft Materials Using a Self-Locked Stretchable Strain Sensor

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

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