Maskless Formation of Conductive Carbon Layer on Leather for Highly Sensitive Flexible Strain Sensors

Wang, Zi-Yang; Chen, Bin; Sun, Shibin; Pan, Likun; Gao, Yang

doi:10.1002/aelm.202000549

Cited by 16 publications

(11 citation statements)

References 49 publications

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“…In existing researches, many scalable fabrication methods have been proposed to fabricate flexible strain sensors, such as photolithography, [20,21] spraying, [22] laser direct writing, [23,24] inkjet printing, [25] pencil-drawn method, [26] and dip-coating method. [27] These methods often require complicated procedures or are not efficient or cost-effective.…”

Section: Introductionmentioning

confidence: 99%

3D Printed Reduced Graphene Oxide/Elastomer Resin Composite with Structural Modulated Sensitivity for Flexible Strain Sensor

et al. 2021

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High-performance flexible strain sensors with cost-effective and scalable fabrication methods are highly demanded for human-machine interfaces, soft robotics, and health monitoring. Herein, a digital light processing-based 3D printing method, which manufactures structures in a scalable and efficient layerby-layer manner, is developed to prepare a type of flexible strain sensors consisting of reduced graphene oxide/elastomer resin (RGO/ER) composite as the strain sensing element and RGO/ER composite with rhombic structure as the electrode. The RGO/ER composite as the sensing element has a sensitivity of 6.723 at a linear strain detection range from 0.01% to 40% and a high mechanical stability of more than 10 000 stretching-relaxing cycles. Furthermore, through the structural modulation, the sensitivity of the composite responding to mechanical deformation is modulated and suppressed, which can be used as the electrode for the strain sensor. The all-3D printed device with structurally modulated performance can be used for monitoring various human motions.

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Section: Introductionmentioning

confidence: 99%

3D Printed Reduced Graphene Oxide/Elastomer Resin Composite with Structural Modulated Sensitivity for Flexible Strain Sensor

et al. 2021

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“…[ 18,19 ] Depending on the intensity of the laser power, one can use a laser to cut materials in various structures [ 20,21 ] or induce chemical reactions in materials, for example, converting carbon‐based polymers to graphene. [ 22–27 ] Here we use a UV laser to create a sensor array from a polymeric multi‐layer stack. We first use low laser power to generate isolated piezoresistive 3D graphene pixels and then turn up the laser power to cut through the active and substrate layers and leave behind an interconnect pattern to connect individual pixels.…”

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Crosstalk‐Free, High‐Resolution Pressure Sensor Arrays Enabled by High‐Throughput Laser Manufacturing

Long

Chen

et al. 2022

Advanced Materials

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Simultaneously achieving high spatial resolution and low crosstalk interference has been a fundamental challenge for flexible pressure sensor arrays. Here the authors present a high-resolution flexible pressure sensor array fabricated through a two-step laser manufacturing process, where individual sensing pixels and their interconnects are sequentially defined by laserinduced graphenization and ablation to minimize crosstalk interferences. The geometry of the interconnects is optimized through theoretical modeling and experimental validation. Characterization results show that the new device design induces a remarkable reduction of the crosstalk coefficient, from −8.21 to −43.63 dB, of the 0.7 mm-resolution sensor arrays, and the crosstalk suppression is particularly beneficial for application scenarios involving pressure sensing on soft surfaces (e.g., human skin and organs). Applications of the sensor array in tactile pattern recognition and minimally-invasive cancer surgery are demonstrated.

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“…32 Liu's group reported a LDW sensor fabricated on polyimide/paper bilayer structure for force and humidity detection. 33 In our previous work, strain and pressure sensors have been fabricated on Ecoflex, 29 textile, 28 and leather 34 by LDW. Although LDW has been regarded as a highly efficient method to fabricate flexible electronics in a mask-free way, a large portion of the above studies only focuses on LDW carbonization of substrates (e.g., PI, PDMS) 35,36 for flexible sensors.…”

Section: Introductionmentioning

confidence: 99%

Laser Direct Writing of Flexible Sensor Arrays Based on Carbonized Carboxymethylcellulose and Its Composites for Simultaneous Mechanical and Thermal Stimuli Detection

Bai

Gao

et al. 2021

ACS Appl. Mater. Interfaces

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Multifunctional sensing devices with high flexibility, high sensitivity, and scalable fabrication are inevitable components of Internet of Things (IoT) for human−machine interfaces, structural health monitoring, and soft robots. Herein, high-performance flexible sensor arrays using carboxymethylcellulose (CMC) and its composite were developed for mechanical and thermal stimuli detection by laser direct writing. CMC contains abundant carbon precursors for strainsensitive laser-carbonized CMC (LC-CMC), while the incorporation of graphene oxide (GO) into CMC leads to the formation of thermalsensitive laser-carbonized GO/CMC (LC-GO/CMC). The LC-CMC-based strain sensor delivers gauge factors of 487.7 (strain < 8.5%) and 8557 (8.5% < strain < 14%), with long-term stability over 10 000 cycles. With 0.2 wt % GO, the LC-GO/CMC-based device provides a temperature coefficient of resistance of −0.289% °C −1 , higher than the Cr-based commercial sensor. The potential application of the devices in IoT is proved by combining the near-field communication technology with the LC-CMC-based device to monitor the strain suffered by 316L stainless steel during the fatigue test. Moreover, an integrated device based on the strain and temperature sensing arrays accomplishes the simultaneous measurement of temperature and mechanical deformation in real time.

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Maskless Formation of Conductive Carbon Layer on Leather for Highly Sensitive Flexible Strain Sensors

Cited by 16 publications

References 49 publications

3D Printed Reduced Graphene Oxide/Elastomer Resin Composite with Structural Modulated Sensitivity for Flexible Strain Sensor

3D Printed Reduced Graphene Oxide/Elastomer Resin Composite with Structural Modulated Sensitivity for Flexible Strain Sensor

Crosstalk‐Free, High‐Resolution Pressure Sensor Arrays Enabled by High‐Throughput Laser Manufacturing

Laser Direct Writing of Flexible Sensor Arrays Based on Carbonized Carboxymethylcellulose and Its Composites for Simultaneous Mechanical and Thermal Stimuli Detection

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