A Flexible Pressure Sensor Based on Graphene/Epoxy Resin Composite Film and Screen Printing Process

Lin, Qijing; Zhang, Fuzheng; Xu, Xiangyue; Yang, Haolin; Mao, Qi; Xian, Dan; Yao, Kun; Meng, Qingzhi

doi:10.3390/nano13192630

Cited by 3 publications

(1 citation statement)

References 56 publications

(55 reference statements)

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“…59 Based on a screen-printing process, Lin et al prepared a high-performance flexible piezoresistive sensor based on Gr and EP, with response and recovery times of 40.8 ms and 3.7 ms, and a pressure detection range of 2.5–500 kPa. 60 The addition of EP increased the bonding force between the substrate and the conductive material, further expanding the application in sensor.…”

Section: Design and Construction Of Flexible Resistive Tactile Sensorsmentioning

confidence: 99%

Flexible resistive tactile pressure sensors

Shu,

Pang,

et al. 2024

J. Mater. Chem. A

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Section: Design and Construction Of Flexible Resistive Tactile Sensorsmentioning

confidence: 99%

Flexible resistive tactile pressure sensors

Shu,

Pang,

et al. 2024

J. Mater. Chem. A

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Carbon Micro/Nano Machining toward Miniaturized Device: Structural Engineering, Large‐Scale Fabrication, and Performance Optimization

Ma,

Wang,

Xiong

et al. 2024

Small

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With the rapid development of micro/nano machining, there is an elevated demand for high‐performance microdevices with high reliability and low cost. Due to their outstanding electrochemical, optical, electrical, and mechanical performance, carbon materials are extensively utilized in constructing microdevices for energy storage, sensing, and optoelectronics. Carbon micro/nano machining is fundamental in carbon‐based intelligent microelectronics, multifunctional integrated microsystems, high‐reliability portable/wearable consumer electronics, and portable medical diagnostic systems. Despite numerous reviews on carbon materials, a comprehensive overview is lacking that systematically encapsulates the development of high‐performance microdevices based on carbon micro/nano structures, from structural design to manufacturing strategies and specific applications. This review focuses on the latest progress in carbon micro/nano machining toward miniaturized device, including structural engineering, large‐scale fabrication, and performance optimization. Especially, the review targets an in‐depth evaluation of carbon‐based micro energy storage devices, microsensors, microactuators, miniaturized photoresponsive and electromagnetic interference shielding devices. Moreover, it highlights the challenges and opportunities in the large‐scale manufacturing of carbon‐based microdevices, aiming to spark further exciting research directions and application prospectives.

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Characterization, impact and wear properties of treated and as-received graphene nanosheets reinforcement in epoxy resin composites

Jazaa

2024

FEBE

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PurposeThis study aims to explore the enhancement of mechanical properties in epoxy resin composites through the incorporation of graphene nanoparticles, focusing on their impact and wear resistance. It investigates the role of graphene, both treated and untreated, as a reinforcing agent in composites, highlighting the significance of nanoparticle dispersion and surfactant treatment in optimizing mechanical performance.Design/methodology/approachEmploying a novel dispersion technique using a drawing brush, this research contrasts with traditional methods by examining the effects of graphene nanoparticle concentrations treated with surfactants – Polyvinylpyrrolidone (PVP) and Sulphonated Naphthalene Formaldehyde (SNF) – on the mechanical properties of epoxy resin composites. The methodology includes conducting a series of impact and wear tests to assess the influence of graphene reinforcement on the composites' performance.FindingsThe findings reveal a marked enhancement in the composites impact resistance and energy absorption capabilities, which escalate with an increase in graphene content. Additionally, the study demonstrates a significant improvement in wear resistance, attributed to the superior mechanical properties, robust interface adhesion and effective dispersion of graphene. The use of surfactants for graphene treatment is identified as a crucial factor in these advancements, offering profound insights into the development of advanced composite materials for diverse industrial uses.Originality/valueThis study introduces a unique dispersion technique for graphene in epoxy composites, setting it apart from conventional methods. By focusing on the critical role of surfactant treatment in enhancing the mechanical properties of graphene-reinforced composites, it provides a novel insight into the optimization of impact and wear resistance.

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A Flexible Pressure Sensor Based on Graphene/Epoxy Resin Composite Film and Screen Printing Process

Cited by 3 publications

References 56 publications

Flexible resistive tactile pressure sensors

Flexible resistive tactile pressure sensors

Carbon Micro/Nano Machining toward Miniaturized Device: Structural Engineering, Large‐Scale Fabrication, and Performance Optimization

Characterization, impact and wear properties of treated and as-received graphene nanosheets reinforcement in epoxy resin composites

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