Tunable Wide Range and High Sensitivity Flexible Pressure Sensors with Ordered Multilevel Microstructures

Da, Geng; Chen, Songyue; Chen, Rui; You, Yu; Xiao, Chiqian; Chen, Bai; Luo, Tao; Zhou, Wei

doi:10.1002/admt.202101031

Cited by 39 publications

(44 citation statements)

References 37 publications

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“…However, when two or more stimuli act simultaneously, studies on the discrimination of stimuli are insufficient, and additionally, there are limitations due to mass production difficulties and low durability. Therefore, studies on structures having a high durability and mass production using microstructures of various shapes are in progress [ 299 , 300 ].…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

Flexible Sensory Systems: Structural Approaches

et al. 2022

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Biology is characterized by smooth, elastic, and nonplanar surfaces; as a consequence, soft electronics that enable interfacing with nonplanar surfaces allow applications that could not be achieved with the rigid and integrated circuits that exist today. Here, we review the latest examples of technologies and methods that can replace elasticity through a structural approach; these approaches can modify mechanical properties, thereby improving performance, while maintaining the existing material integrity. Furthermore, an overview of the recent progress in wave/wrinkle, stretchable interconnect, origami/kirigami, crack, nano/micro, and textile structures is provided. Finally, potential applications and expected developments in soft electronics are discussed.

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Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

Flexible Sensory Systems: Structural Approaches

et al. 2022

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“…Metal materials also include various metal nanomaterials (nano-silver [ 47 , 48 ] and nano-gold [ 38 , 49 ]), metal thin-film materials (thin-film copper [ 50 ] and thin-film magnesium [ 51 ]), metal oxides [ 13 ], liquid metals [ 52 ], etc. Ordinary carbon materials include carbon nanotubes [ 53 , 54 ], carbon black [ 55 ], bio-derived carbon materials [ 56 , 57 ], etc. New two-dimensional materials include not only graphenes [ 40 , 58 , 59 , 60 ] and redox graphene [ 61 , 62 ] that have attracted much attention but also transition metal two-dimensional materials that have emerged in recent years (transition metal carbonitride Mxenes [ 63 , 64 ], two-dimensional transition metal chalcogenides TMDs [ 65 ]; conductive organic materials include PPy [ 66 , 67 ], PEDOT:PSS [ 68 , 69 ], etc.…”

Section: Fundamental Designs Of Flexible Pressure Sensorsmentioning

confidence: 99%

“…Due to the fact that the micro-nano-multilevel structure obtained from the outside world cannot control the distribution of the structure, some research groups process the required micro-nano-multilevel structure by artificial means. Zhou et al prepared flexible piezoresistive sensors with multilevel structures through low-cost laser marking technology, template technology, and spraying technology [ 55 ]. As shown in Figure 4 c, the desired ordered micro-nano-multilevel structure can be prepared by laser marking technology, and the sensing performance of the flexible sensor can be adjusted.…”

Section: Sensor Designs With Force-sensitive Interface Engineeringmentioning

confidence: 99%

“…Micro-nano-multilevel structure: ( c ) Micro-nano-multilevel structure obtained by laser marking method. Reprinted with permission from reference [ 55 ] (Copyright © 2021 Wiley-VCH GmbH), ( d ) The micro-nano-multilevel structure obtained by sandpaper is used for the dielectric layer. Reproduced with permission from reference [ 38 ].…”

Section: Sensor Designs With Force-sensitive Interface Engineeringmentioning

confidence: 99%

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Force-Sensitive Interface Engineering in Flexible Pressure Sensors: A Review

Tai

Wei

et al. 2022

Sensors

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Flexible pressure sensors have received extensive attention in recent years due to their great importance in intelligent electronic devices. In order to improve the sensing performance of flexible pressure sensors, researchers are committed to making improvements in device materials, force-sensitive interfaces, and device structures. This paper focuses on the force-sensitive interface engineering of the device, which listing the main preparation methods of various force-sensitive interface microstructures and describing their respective advantages and disadvantages from the working mechanisms and practical applications of the flexible pressure sensor. What is more, the device structures of the flexible pressure sensor are investigated with the regular and irregular force-sensitive interface and accordingly the influences of different device structures on the performance are discussed. Finally, we not only summarize diverse practical applications of the existing flexible pressure sensors controlled by the force-sensitive interface but also briefly discuss some existing problems and future prospects of how to improve the device performance through the adjustment of the force-sensitive interface.

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“…Recently, multistage microstructures 24 and gradient pore structures 22 have been proposed to resolve the abovementioned problems. For example, the piezoresistive pressure sensor with a multilevel microdome structure designed by Geng et al 27 showed sensitivity (1.5−8.3 kPa −1 ) in a wide range (0.01−200 kPa). The multistage structure or gradient pore structure can deform gradually with increasing pressure and thus leads to a considerable sensitivity in a wide detection range.…”

Section: Introductionmentioning

confidence: 99%

Ag Nanowire/CPDMS Dual Conductive Layer Dome-Based Flexible Pressure Sensor with High Sensitivity and a Wide Linear Range

Wang

Zhong

Dai

et al. 2022

ACS Appl. Nano Mater.

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Recent research achievements for flexible pressure sensors have promoted promising applications, such as human health detection and intelligent robotics. However, striking a balance between sensitivity and linear detection range is still a challenge. In this paper, a dual conductive layer dome (DCLD) structure, where a silver (Ag) nanowire layer is used as a highly conductive layer and the composite layer of carbon black nanoparticles and polydimethylsiloxane (CPDMS) serves as a low conductive layer, is fabricated with a scratch coating process followed by dip-coating and vacuum adsorption. Benefitting from the dual conductive layer design, the sensitivity of the DCLD sensor reaches 51.7 kPa −1 over an ultrawide pressure of 0.01−250 kPa, which is far better than the CPDMS single conductive layer dome (SCLD). The circuit models of DCLD and SCLD are proposed to disclose their working mechanism. The effects of carbon black nanoparticle ratio in CPDMS and the structural matching between the DCLD structure and electrode on the sensor's performance are explored. The long-cycle stability of DCLD sensors with different fabrication methods is also compared. Additionally, it has been demonstrated that the sensor is efficient in monitoring human motion, such as finger joint flexion, pulse pulses, and human breathing, showing potential in the field of human health monitoring.

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Tunable Wide Range and High Sensitivity Flexible Pressure Sensors with Ordered Multilevel Microstructures

Cited by 39 publications

References 37 publications

Flexible Sensory Systems: Structural Approaches

Flexible Sensory Systems: Structural Approaches

Force-Sensitive Interface Engineering in Flexible Pressure Sensors: A Review

Ag Nanowire/CPDMS Dual Conductive Layer Dome-Based Flexible Pressure Sensor with High Sensitivity and a Wide Linear Range

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