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Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network

Flexible strain sensors, when considering high sensitivity and a large strain range, have become a key requirement for current robotic applications. However, it is still a thorny issue to take both factors into consideration at the same time. Here, we report a sandwich-structured strain sensor based...

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Autores principales: Li, Rui, Gou, Xin, Li, Xinyan, Wang, Hainuo, Ruan, Haibo, Xiong, Yuting, Tang, Xianlun, Li, Yuanyuan, Yang, Ping-an
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2022
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9331932/
https://www.ncbi.nlm.nih.gov/pubmed/35897893
http://dx.doi.org/10.3390/molecules27154717
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author Li, Rui
Gou, Xin
Li, Xinyan
Wang, Hainuo
Ruan, Haibo
Xiong, Yuting
Tang, Xianlun
Li, Yuanyuan
Yang, Ping-an
author_facet Li, Rui
Gou, Xin
Li, Xinyan
Wang, Hainuo
Ruan, Haibo
Xiong, Yuting
Tang, Xianlun
Li, Yuanyuan
Yang, Ping-an
author_sort Li, Rui
collection PubMed
description Flexible strain sensors, when considering high sensitivity and a large strain range, have become a key requirement for current robotic applications. However, it is still a thorny issue to take both factors into consideration at the same time. Here, we report a sandwich-structured strain sensor based on Fe nanowires (Fe NWs) that has a high GF (37–53) while taking into account a large strain range (15–57.5%), low hysteresis (2.45%), stability, and low cost with an areal density of Fe NWs of 4.4 mg/cm(2). Additionally, the relationship between the contact point of the conductive network, the output resistance, and the areal density of the sensing unit is analyzed. Microscopically, the contact points of the conductive network directly affect the sensor output resistance distribution, thereby affecting the gauge factor (GF) of the sensor. Macroscopically, the areal density and the output resistivity of the strain sensor have the opposite percolation theory, which affects its linearity performance. At the same time, there is a positive correlation between the areal density and the contact point: when the stretching amount is constant, it theoretically shows that the areal density affects the GF. When the areal density reaches this percolation threshold range, the sensing performance is the best. This will lay the foundation for rapid applications in wearable robots.
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spelling pubmed-93319322022-07-29 Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network Li, Rui Gou, Xin Li, Xinyan Wang, Hainuo Ruan, Haibo Xiong, Yuting Tang, Xianlun Li, Yuanyuan Yang, Ping-an Molecules Article Flexible strain sensors, when considering high sensitivity and a large strain range, have become a key requirement for current robotic applications. However, it is still a thorny issue to take both factors into consideration at the same time. Here, we report a sandwich-structured strain sensor based on Fe nanowires (Fe NWs) that has a high GF (37–53) while taking into account a large strain range (15–57.5%), low hysteresis (2.45%), stability, and low cost with an areal density of Fe NWs of 4.4 mg/cm(2). Additionally, the relationship between the contact point of the conductive network, the output resistance, and the areal density of the sensing unit is analyzed. Microscopically, the contact points of the conductive network directly affect the sensor output resistance distribution, thereby affecting the gauge factor (GF) of the sensor. Macroscopically, the areal density and the output resistivity of the strain sensor have the opposite percolation theory, which affects its linearity performance. At the same time, there is a positive correlation between the areal density and the contact point: when the stretching amount is constant, it theoretically shows that the areal density affects the GF. When the areal density reaches this percolation threshold range, the sensing performance is the best. This will lay the foundation for rapid applications in wearable robots. MDPI 2022-07-23 /pmc/articles/PMC9331932/ /pubmed/35897893 http://dx.doi.org/10.3390/molecules27154717 Text en © 2022 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Li, Rui
Gou, Xin
Li, Xinyan
Wang, Hainuo
Ruan, Haibo
Xiong, Yuting
Tang, Xianlun
Li, Yuanyuan
Yang, Ping-an
Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network
title Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network
title_full Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network
title_fullStr Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network
title_full_unstemmed Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network
title_short Improved Stretchable and Sensitive Fe Nanowire-Based Strain Sensor by Optimizing Areal Density of Nanowire Network
title_sort improved stretchable and sensitive fe nanowire-based strain sensor by optimizing areal density of nanowire network
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9331932/
https://www.ncbi.nlm.nih.gov/pubmed/35897893
http://dx.doi.org/10.3390/molecules27154717
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