Microengineering Pressure Sensor Active Layers for Improved Performance

Ruth, Sara Rachel Arussy; Feig, Vivian R.; Tran, Helen; Bao, Zhenan

doi:10.1002/adfm.202003491

Cited by 347 publications

(307 citation statements)

References 148 publications

(488 reference statements)

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“…Micro‐pillars, micro‐bumps, and micro‐structures as dielectric material have been widely explored for more than a decade in the design of highly sensitive flexible capacitive pressure sensors. [ 103,104 ] Micro‐arrays are developed by casting PDMS on silicon mold and then ITO/PET thin film that acts as electrodes is laminated on the PDMS [ Figure a]. [ 105 ] After peeling off the ITO/PET thin film from the silicon mold, the PDMS micro‐arrays are formed, as shown in the scanning electron microscope (SEM) image [Figure 7b].…”

Section: Types Of Flexible Capacitive Pressure Sensorsmentioning

confidence: 99%

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Mishra

El‐Atab

Hussain

et al. 2021

Adv Materials Technologies

188

117

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For decades, the revolution in design and fabrication methodology of flexible capacitive pressure sensors using various inorganic/organic materials has significantly enhanced the field of flexible and wearable electronics with a wide range of applications in aerospace, automobiles, marine environment, robotics, healthcare, and consumer/portable electronics. Mathematical modelling, finite element simulations, and unique fabrication strategies are utilized to fabricate diverse shapes of diaphragms, shells, and cantilevers which function in normal, touch, or double touch modes, operation principles inspired from microelectromechanical systems (MEMS) based capacitive pressure sensing techniques. The capacitive pressure sensing technique detects changes in capacitance due to the deformation/deflection of a pressure sensitive mechanical element that alters the separation gap of the capacitor. Due to advancement in state‐of‐the‐art fabrication technologies, the performance and properties of capacitive pressure sensors are enhanced. In this review paper, recent progress in flexible capacitive pressure sensing techniques in terms of design, materials, and fabrication strategies is reported. The mechanics and fabrication steps of paper‐based low‐cost MEMS/flexible devices are also broadly reported. Lastly, the applications of flexible capacitive pressure sensors, challenges, and future perspectives are discussed.

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Section: Types Of Flexible Capacitive Pressure Sensorsmentioning

confidence: 99%

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Mishra

El‐Atab

Hussain

et al. 2021

Adv Materials Technologies

188

117

View full text Add to dashboard Cite

show abstract

“…Highly sensitive pressure sensors have been obtained by microstructuring the dielectric layer, which causes compression to also displace air within that layer. [ 33,41–43,45–52 ] As air has a lower dielectric constant than the dielectric material, this change causes an increase in the overall effective dielectric constant of the layer, which further increases the change in capacitance upon compression. [ 43,46 ]…”

Section: Resultsmentioning

confidence: 99%

Flexible Fringe Effect Capacitive Sensors with Simultaneous High‐Performance Contact and Non‐Contact Sensing Capabilities

et al. 2020

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To mimic human touch sensing, robotics must be able to leverage multiple sensory inputs. Previously, to achieve both proximity and pressure sensing, most approaches have required using two separate sensors, each with their corresponding electronics, limiting the achievable density. More recently, sensors with multifunctional pressure and proximity capabilities have been realized at the cost of compromised pressure sensing. Presented here is a new design for a multifunctional interdigitated fringe field capacitive pressure sensor with a pyramid microstructured dielectric layer that has proximity‐sensing capabilities (noncontact mode) while also sensing pressure (contact mode) as strongly as an equivalent parallel plate capacitive sensor of the same size. In contact mode, both sensors have a response time of less than 20 ms and can respond to loads lighter than 0.5 Pa. Further, the interdigitated fringe field sensor can clearly distinguish between the two sensing modes, as well as between conductive and nonconductive materials in the noncontact mode. Finally, we use the interdigitated fringe field sensor to demonstrate both proximity and high‐sensitivity pressure sensing on a robotic gripper.

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“…The sensing performance of the sensor is projected to be affected by the surface area and deformation of the microstructure. [39][40][41][42] Changes in resistance upon the application of a repeated pressure of 88.89 kPa were detected. It can be clearly seen in Figure 5c that the relative change in resistance is almost the same (over 1000 cycles were tested in the experiments), which demonstrated high durability and stability.…”

Section: Interlocked Domes For Wearable Sensorsmentioning

confidence: 99%

Amalgamation‐Assisted Control of Profile of Liquid Metal for the Fabrication of Microfluidic Mixer and Wearable Pressure Sensor

Tang

et al. 2021

Adv Materials Inter

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The presence of microdomes can significantly increase the surface roughness, contact area, and deformability of materials, which have been adopted in many fields including microfluidics, wearable devices, and microanalysis systems. However, the shape of liquid metal (LM) droplet is defined by the density and surface energy, which has very limited room to tune. In this work, a simple, low‐cost method to effectively control the profile of LM using the masked amalgamation is presented. The LM amalgamates the masked copper surface to create the complex microdomes with various aspect ratios, sizes, profiles, and structures. The concave dome replicated from the LM mold has been demonstrated to enhance the microfluidic mixing performance. With a pattern transfer technique, the microconvex domes can be patterned on the surface of stretchable conductive composites to develop a flexible and sensitive pressure sensor. This sensor exhibits a fast response time, a wide working range, and an enhanced sensitivity for detecting small strains. As such, the fabricated microdomes exhibit a great potential to enable the fabrication of high‐performance sensors, microfluidic platforms, and micro total analysis systems.

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Microengineering Pressure Sensor Active Layers for Improved Performance

Cited by 347 publications

References 148 publications

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Flexible Fringe Effect Capacitive Sensors with Simultaneous High‐Performance Contact and Non‐Contact Sensing Capabilities

Amalgamation‐Assisted Control of Profile of Liquid Metal for the Fabrication of Microfluidic Mixer and Wearable Pressure Sensor

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