Journal Article10.1002/ADMA.202103320
Highly Sensitive Capacitive Pressure Sensors over a Wide Pressure Range Enabled by the Hybrid Responses of a Highly Porous Nanocomposite
Kyoung-Ho Ha,Weiyi Zhang,Hongwoo Jang,Seungmin Kang,Liu Wang,Philip Tan,Hochul Hwang,Nanshu Lu +7 more
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TL;DR: In this paper, a flexible hybrid response pressure sensor (HRPS) composed of an electrically conductive porous nanocomposite (PNC) laminated with an ultrathin dielectric layer is devised.
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Abstract: Past research aimed at increasing the sensitivity of capacitive pressure sensors has mostly focused on developing dielectric layers with surface/porous structures or higher dielectric constants. However, such strategies have only been effective in improving sensitivities at low pressure ranges (e.g., up to 3 kPa). To overcome this well-known obstacle, herein, a flexible hybrid-response pressure sensor (HRPS) composed of an electrically conductive porous nanocomposite (PNC) laminated with an ultrathin dielectric layer is devised. Using a nickel foam template, the PNC is fabricated with carbon nanotubes (CNTs)-doped Ecoflex to be 86% porous and electrically conductive. The PNC exhibits hybrid piezoresistive and piezocapacitive responses, resulting in significantly enhanced sensitivities (i.e., more than 400%) over wide pressure ranges, from 3.13 kPa-1 within 0-1 kPa to 0.43 kPa-1 within 30-50 kPa. The effect of the hybrid responses is differentiated from the effect of porosity or high dielectric constants by comparing the HRPS with its purely piezocapacitive counterparts. Fundamental understanding of the HRPS and the prediction of optimal CNT doping are achieved through simplified analytical models. The HRPS is able to measure pressures from as subtle as the temporal arterial pulse to as large as footsteps.
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Citations
Electromechanics of Soft Resistive and Capacitive Tactile Sensors
Zhengjie Li,Sangjun Kim,Zheliang Wang,Zhengtao Zhu,Nanshu Lu +4 more
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TL;DR: This chapter explores electromechanical models to understand relationships between materials, structures, and performance of soft resistive and capacitive tactile sensors, addressing challenges in electronic skin development for human and robotic applications.
Body-coupled minimalist human-machine interface for multifunctional touch detection
Guoliang Ma,Hu Shen,Congtian Gu,Liaoyuan Pu,Kaixian Ba,Da-Kai Wang,Bin Yu,Zhiwu Han,Luquan Ren,Guoliang Ma,Hu Shen,Congtian Gu,Liaoyuan Pu,Kaixian Ba,Da-Kai Wang,Bin Yu,Zhiwu Han,Luquan Ren +17 more
Abstract: Human-machine interfaces (HMI) are of paramount importance as they serve as essential conduits between humans and the digital realm. However, contemporary designs suffer from the following issues: large number of electrodes, complex wiring, redundant data, and high power consumption. This work proposes a body-coupled minimalist human-machine interface for multifunctional touch detection (BM-HMI). The configuration of gradient resistive elements in the S-shape, in conjunction with a detection strategy founded upon the ratio of relative signal amplitudes, facilitates the effective detection of signals across a range of touch and sliding operations utilizing a mere two sensing electrodes. The experimental results demonstrate that the BM-HMI requires no battery, has remarkable stability (over 400,000 cycles), structural simplicity, rapid response time (approximately 5 ms), ultra-low detection threshold (below 0.04 N), robustness, and high scalability. This work presents a novel concept, demonstrating considerable potential for application in smart wearable devices, mixed reality systems, and ubiquitous sensing terminals.
Vapor-induced porosity in graphene/PDMS: a scalable route to high-performance pressure sensors
Nadeem Tariq Beigh,Nouha Alcheikh,Nadeem Tariq Beigh,Nouha Alcheikh +3 more
3D Printing of Capacitive Pressure Sensors with Tuned Wide Detection Range and High Sensitivity Inspired by Bio-Inspired Kapok Structures.
Qingxin Jin,Chengyun Wang,Han Wu,Xin Luo,Jiaqi Li,Guangmeng Ma,Yu Li,Chunyi Luo,Fawei Guo,Yu Long +9 more
TL;DR: 3D printed capacitive pressure sensors with a wide detection range and high sensitivity inspired by bio-inspired kapok structures exhibit remarkable features such as high sensitivity, broad detection range, fast response time, and outstanding pressure resolution.
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