Ultrasensitive, Fast-Responsive, Directional Airflow Sensing by Bioinspired Suspended Graphene Fibers

Libei Huang; Yong Liu; Geng Li; Yun Song; Jianjun Su; Le Cheng; Weihua Guo; Ganggang Zhao; Hanchen Shen; Zheng Yan; Ben Zhong Tang; Ruquan Ye

doi:10.1021/acs.nanolett.2c04228

Ultrasensitive, Fast-Responsive, Directional Airflow Sensing by Bioinspired Suspended Graphene Fibers

Libei Huang, Yong Liu, Geng Li, Yun Song, Jianjun Su, Le Cheng, Weihua Guo, Ganggang Zhao, Hanchen Shen, Zheng Yan^*, Ben Zhong Tang, Ruquan Ye^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

50 Citations (Scopus)

Abstract

The development of high-performance miniaturized and flexible airflow sensors is essential to meet the need of emerging applications. Graphene-based airflow sensors are hampered by the sluggish response and recovery speed and low sensitivity. Here we employ laser-induced graphene (LIG) with poststructural biomimicry for fabricating high-performance, flexible airflow sensors, including cotton-like porous LIG, caterpillar fluff-like vertical LIG fiber, and Lepidoptera scale-like suspended LIG fiber (SLIGF) structures. The structural engineering changes the deformation behavior of LIGs under stress, among which the synchronous propagation of the scale-like structure of SLIGF is the most conducive to airflow sensing. The SLIGF achieves the shortest average response time of 0.5 s, the highest sensitivity of 0.11 s/m, and a record-low detection threshold of 0.0023 m/s, benchmarked against the state-of-the-art airflow sensors. Furthermore, we showcase the SLIGF airflow sensors in weather forecasting, health, and communications applications. Our study will help develop next-generation waterflow, sound, and motion sensors.

Original language	English
Pages (from-to)	597–605
Journal	Nano Letters
Volume	23
Issue number	2
Online published	9 Jan 2023
DOIs	https://doi.org/10.1021/acs.nanolett.2c04228
Publication status	Published - 25 Jan 2023

Research Keywords

airflow sensor
biomimicry
domino effect
laser-induced graphene
scale-like

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10.1021/acs.nanolett.2c04228

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title = "Ultrasensitive, Fast-Responsive, Directional Airflow Sensing by Bioinspired Suspended Graphene Fibers",

abstract = "The development of high-performance miniaturized and flexible airflow sensors is essential to meet the need of emerging applications. Graphene-based airflow sensors are hampered by the sluggish response and recovery speed and low sensitivity. Here we employ laser-induced graphene (LIG) with poststructural biomimicry for fabricating high-performance, flexible airflow sensors, including cotton-like porous LIG, caterpillar fluff-like vertical LIG fiber, and Lepidoptera scale-like suspended LIG fiber (SLIGF) structures. The structural engineering changes the deformation behavior of LIGs under stress, among which the synchronous propagation of the scale-like structure of SLIGF is the most conducive to airflow sensing. The SLIGF achieves the shortest average response time of 0.5 s, the highest sensitivity of 0.11 s/m, and a record-low detection threshold of 0.0023 m/s, benchmarked against the state-of-the-art airflow sensors. Furthermore, we showcase the SLIGF airflow sensors in weather forecasting, health, and communications applications. Our study will help develop next-generation waterflow, sound, and motion sensors.",

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author = "Libei Huang and Yong Liu and Geng Li and Yun Song and Jianjun Su and Le Cheng and Weihua Guo and Ganggang Zhao and Hanchen Shen and Zheng Yan and Tang, {Ben Zhong} and Ruquan Ye",

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T1 - Ultrasensitive, Fast-Responsive, Directional Airflow Sensing by Bioinspired Suspended Graphene Fibers

AU - Huang, Libei

AU - Liu, Yong

AU - Li, Geng

AU - Song, Yun

AU - Su, Jianjun

AU - Cheng, Le

AU - Guo, Weihua

AU - Zhao, Ganggang

AU - Shen, Hanchen

AU - Yan, Zheng

AU - Tang, Ben Zhong

AU - Ye, Ruquan

PY - 2023/1/25

Y1 - 2023/1/25

N2 - The development of high-performance miniaturized and flexible airflow sensors is essential to meet the need of emerging applications. Graphene-based airflow sensors are hampered by the sluggish response and recovery speed and low sensitivity. Here we employ laser-induced graphene (LIG) with poststructural biomimicry for fabricating high-performance, flexible airflow sensors, including cotton-like porous LIG, caterpillar fluff-like vertical LIG fiber, and Lepidoptera scale-like suspended LIG fiber (SLIGF) structures. The structural engineering changes the deformation behavior of LIGs under stress, among which the synchronous propagation of the scale-like structure of SLIGF is the most conducive to airflow sensing. The SLIGF achieves the shortest average response time of 0.5 s, the highest sensitivity of 0.11 s/m, and a record-low detection threshold of 0.0023 m/s, benchmarked against the state-of-the-art airflow sensors. Furthermore, we showcase the SLIGF airflow sensors in weather forecasting, health, and communications applications. Our study will help develop next-generation waterflow, sound, and motion sensors.

AB - The development of high-performance miniaturized and flexible airflow sensors is essential to meet the need of emerging applications. Graphene-based airflow sensors are hampered by the sluggish response and recovery speed and low sensitivity. Here we employ laser-induced graphene (LIG) with poststructural biomimicry for fabricating high-performance, flexible airflow sensors, including cotton-like porous LIG, caterpillar fluff-like vertical LIG fiber, and Lepidoptera scale-like suspended LIG fiber (SLIGF) structures. The structural engineering changes the deformation behavior of LIGs under stress, among which the synchronous propagation of the scale-like structure of SLIGF is the most conducive to airflow sensing. The SLIGF achieves the shortest average response time of 0.5 s, the highest sensitivity of 0.11 s/m, and a record-low detection threshold of 0.0023 m/s, benchmarked against the state-of-the-art airflow sensors. Furthermore, we showcase the SLIGF airflow sensors in weather forecasting, health, and communications applications. Our study will help develop next-generation waterflow, sound, and motion sensors.

KW - airflow sensor

KW - biomimicry

KW - domino effect

KW - laser-induced graphene

KW - scale-like

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U2 - 10.1021/acs.nanolett.2c04228

DO - 10.1021/acs.nanolett.2c04228

M3 - RGC 21 - Publication in refereed journal

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JO - Nano Letters

JF - Nano Letters

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ER -

Ultrasensitive, Fast-Responsive, Directional Airflow Sensing by Bioinspired Suspended Graphene Fibers

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Research Keywords

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DON_RMG: Investigating the Antiviral and Antibacterial Activities of Laser-induced Graphene - RMGS

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Ultrasensitive, Fast-Responsive, Directional Airflow Sensing by Bioinspired Suspended Graphene Fibers

Abstract

Research Keywords

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DON_RMG: Investigating the Antiviral and Antibacterial Activities of Laser-induced Graphene - RMGS

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