Cicada-Wing-Inspired Highly Sensitive Tactile Sensors Based on Elastic Carbon Foam with Nanotextured Surfaces

Chang, Kangqi; Wu, Zhenzhong; Meng, Jian; Guo, Minhao; Yan, Xiu‐Ping; Ma, Piming; Zhao, Jianhua; Wang, Fangneng; Huang, Yunpeng; Liu, Tianxi

doi:10.1021/acsami.2c22204

Cited by 6 publications

(4 citation statements)

References 50 publications

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“…Flexible sensors, − on the other hand, have garnered significant attention due to their small size, high sensitivity, and comfortable wearability. Electronic skin (e-skin) emulates the tactile functionalities of human skin, − allowing for multiple sensing capabilities such as strain, , vibration, pressure, and temperature. As a result, this technology holds vast potential in applications such as smart robotics, prosthetics, human–machine interfaces, − and wearable medical systems. , The ideal electronic skin should possess multifunctional sensing capabilities, which means that it should be able to detect different types of stimuli simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Hierarchically Structured MXene Nanosheets on Carbon Sponges with a Synergistic Effect of Electrostatic Adsorption and Capillary Action for Highly Sensitive Pressure Sensors

et al. 2023

ACS Appl. Nano Mater.

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A highly sensitive pressure sensor with nanoscale features was developed based on the gradient concentration of Ti 3 C 2 T x (MXene). The fabrication strategy involved electrostatic adsorption and capillary action utilizing a carbonized sponge as the substrate. In this approach, hexadecyl trimethyl ammonium bromide (CTAB) was added dropwise to the bottom of the carbonized melamine sponge, facilitating the self-assembly of MXene and achieving a gradient attachment of conductive fillers onto the substrate. Furthermore, a layer of polyvinyl alcohol fibers was electrospun between the sensor bottom and the electrode to enhance sensor sensitivity. The pressure-sensitive sensor prepared by this method exhibited an exceptionally strong response within the pressure range of 0−3 kPa. It demonstrated an ultrahigh sensitivity of 381.91 kPa −1 , with a rapid deformation response of 100 ms and a quick recovery response of 30 ms. Notably, the sensor also demonstrated outstanding durability, enduring 8000 loading− unloading cycles without performance degradation. Moreover, it achieved a minimum detection limit as low as 0.1 Pa. Finite element numerical analysis confirmed that the MXene/CTAB/CMF composite prepared using this approach exhibited superior sensing performance under similar deformation conditions. Importantly, this pressure sensor's exceptional sensing capabilities extended to detecting various physiological signals in the human body and daily work scenarios. When integrated with a microprocessor, it accurately processed complex data sets, highlighting its great potential for practical applications.

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Section: Introductionmentioning

confidence: 99%

Hierarchically Structured MXene Nanosheets on Carbon Sponges with a Synergistic Effect of Electrostatic Adsorption and Capillary Action for Highly Sensitive Pressure Sensors

et al. 2023

ACS Appl. Nano Mater.

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“…[ 13–14 ] Among these, piezoresistive tactile sensors have widely been studied owing to their straightforward design, cost‐effectiveness, and simple operation. [ 3,4,15 ]…”

Section: Introductionmentioning

confidence: 99%

“…[13][14] Among these, piezoresistive tactile sensors have widely been studied owing to their straightforward design, costeffectiveness, and simple operation. [3,4,15] However, despite the significant progress made in the development of wearable piezoresistive tactile sensors, some critical issues still require solutions. For example, piezoresistive materials are limited in terms of safety and biocompatibility in medical settings, and availability under harsh conditions.…”

Section: Introductionmentioning

confidence: 99%

“…Tactile perception is of paramount importance to achieve environmental awareness and human-machine interactions in DOI: 10.1002/admt.202301196 sophisticated applications of smart wearables and intelligent robots. [1,2] Inspired by human skin, various wearable tactile sensors have been proposed over the past decade for precise and rapid sensing based on different mechanisms, including piezoresistive, [3][4][5][6][7][8] capacitive, [9,10] optical, [11] magnetic, [12] and triboelectric mechanisms. [13][14] Among these, piezoresistive tactile sensors have widely been studied owing to their straightforward design, costeffectiveness, and simple operation.…”

Section: Introductionmentioning

confidence: 99%

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Anti‐Freezing Wearable Tactile Sensors Prepared by Laser Processing of Crumpled Xanthan Gum‐Based Hydrogels

Zhang,

Huang,

Zhou

et al. 2023

Adv Materials Technologies

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Wearable piezoresistive tactile sensors are becoming increasingly popular in fields related to human motion/health monitoring, and artificial intelligence. However, piezoresistive materials are still limited in terms of safety and biocompatibility in medical settings, as well as availability under harsh conditions. Herein, elastic and biocompatible hydrogels are prepared by cross‐linking of xanthan gum, polyvinyl alcohol, carbon nanotubes, and glycerol. The presence of glycerol results in hydrogel exhibiting an outstanding freezing resistance (−40 °C). Meanwhile, the controllable, large‐scale, and facile two‐step direct laser writing process allows the fabrication of hydrogels with double‐rough surface structures. By tuning surface roughness, the sensors with the resulting hydrogels show a wide detection range with high sensitivities of 27.5, 5.4, and 2.1 kPa−1 under pressures of 0.1–6, 6–25, and 25–80 kPa. The sensors also display fast response time (≈126 ms), low detection limit (2.26 Pa), good reproducibility of sensing performance (1000 cycles), relevant freezing tolerance (−40 °C), and decent environmental stability (over 30 days). This work provides a low‐cost, ease of manipulation, high reproducible, and large‐scale way for the microstructure engineering of natural‐polymer hydrogels and promotes their widespread applications.

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MXene@CTAB@CMF three-dimensional elastic base for piezoresistive pressure sensors realized by electrostatic self-assembly

Yin,

Li,

et al. 2023

Appl. Phys. A

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Cicada-Wing-Inspired Highly Sensitive Tactile Sensors Based on Elastic Carbon Foam with Nanotextured Surfaces

Cited by 6 publications

References 50 publications

Hierarchically Structured MXene Nanosheets on Carbon Sponges with a Synergistic Effect of Electrostatic Adsorption and Capillary Action for Highly Sensitive Pressure Sensors

Hierarchically Structured MXene Nanosheets on Carbon Sponges with a Synergistic Effect of Electrostatic Adsorption and Capillary Action for Highly Sensitive Pressure Sensors

Anti‐Freezing Wearable Tactile Sensors Prepared by Laser Processing of Crumpled Xanthan Gum‐Based Hydrogels

MXene@CTAB@CMF three-dimensional elastic base for piezoresistive pressure sensors realized by electrostatic self-assembly

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