Conformal manufacturing of soft deformable sensors on the curved surface

Zhang, Wanqing; Zhang, Ling; Liao, Yabin; Cheng, Huanyu

doi:10.1088/2631-7990/ac1158

Cited by 85 publications

(44 citation statements)

References 170 publications

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“…[18] Through the design of new device formats and the introduction of functional materials, several features have been successfully implemented in the devices, including wearable display, [19] information encryption, [20] visualized sensing, [21] soft robots, [8] and motion tracking. [22] Combined with 3D freeform surfaces preparation methods, [23][24][25] the devices can be manufactured on the surface of any objects. These all indicate their immense potential for next-generation optoelectronics.…”

mentioning

confidence: 99%

Asymmetrically Enhanced Coplanar‐Electrode Electroluminescence for Information Encryption and Ultrahighly Stretchable Displays

et al. 2022

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Traditional alternating‐current‐driven electroluminescent (AC‐EL) devices adopting a sandwich structure are commonly used in solid‐state lighting and displays, while the emerging coplanar‐electrode alternating‐current‐driven light‐emitting variants manifest excellent application prospects in intelligent, multifunctional, and full‐color displays, and sensing purposes. In this work, an asymmetrically enhanced coplanar‐electrode AC‐EL device with a universal and straightforward architecture is designed based on the impedance adjustment strategy. This newly devised asymmetric structure extends the functionalities of the coplanar‐electrode AC‐EL devices by overcoming the bottlenecks of complicated patterning procedures and high driving voltages of symmetric configuration. The developed device design enables a new type of information encryption and ultrahighly stretchable patterned displays. Notably, the novel encryption appliances demonstrate feasible encryption/decryption features, multiple encryptions, and practical applicability; the biaxially stretchable display devices achieve the highest tensile performance in the field of stretchable electroluminescent pattern displays, and outperform the ultrahighly stretchable sandwich devices in terms of simple patterning process, higher brightness, wider color gamut, and long‐term stability. The proposed configuration opens up new avenues for AC‐EL devices toward a plethora of smart applications in wearable electronics with intelligent displays, dynamic interaction of human‐machine interface, and soft robotics.

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confidence: 99%

Asymmetrically Enhanced Coplanar‐Electrode Electroluminescence for Information Encryption and Ultrahighly Stretchable Displays

et al. 2022

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“…Recent progress in this field has brought remarkable advances, leading to a variety of curved devices with unique applications in human-computer interaction, imaging, and environmental sensing. [17][18][19] Currently, deterministically patterned stretchable circuits (e.g., circuits employing an island-bridge structure or a local strain suppression layer) form the basis for the most complex, cutting-edge examples of nondevelopable electronics, including thin-film transistors, [20] ultrasonic transducers, [13] curved imagers, [14,21] and thermoelectric energy harvesters. [22] These devices integrate small chip devices, often made of high-performance electronic materials such as silicon or metal, with wavy or kirigamiinspired interconnects, ensuring that any tensile strain applied to the system is concentrated in the wiring instead of the chips.…”

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confidence: 99%

Developing the Nondevelopable: Creating Curved‐Surface Electronics from Nonstretchable Devices

et al. 2021

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The incorporation of electronics onto curved surfaces promises to bring new levels of intelligence to the ergonomic, aesthetic, aerodynamic, and optical surfaces that are ever‐present in our lives. However, since many of these surfaces have 2D (i.e., nondevelopable) curvature, they cannot be formed from the deformation of a flat, nonstretchable sheet. This means that curved electronics cannot capitalize on the rapid technological advances taking place in the field of ultrathin electronics, since ultrathin devices, though ultraflexible, are not stretchable. In this work, a shrink‐based paradigm is presented to apply such thin‐film electronics to nondevelopable surfaces, expanding the capabilities of current nondevelopable electronics, and linking future developments in thin‐film technology to similar developments in curved devices. The wrinkling of parylene‐based devices and the effects of shrinkage on common electrical components are examined, culminating in shrinkable touch sensors and organic photovoltaics, laminated to various nondevelopable surfaces without loss of performance.

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“…Flexible, stretchable and wearable strain sensors have received extensive attention recently because large strains can be applied on the flexible/bendable/stretchable or curved substrates. They effectively change complex mechanical deformations into electrical signals, promising for applications in human health-monitoring systems, wearable internet of things (WIoT), human–machine interaction and soft robotics, etc 1 – 5 . These stretchable/flexible/wearable strain sensors can withstand a much larger strain (up to 500 %) and significant deformation when compared with their rigid counterparts (normally with a strain smaller than 5%) 6 .…”

Section: Introductionmentioning

confidence: 99%

Multiscale and hierarchical wrinkle enhanced graphene/Ecoflex sensors integrated with human-machine interfaces and cloud-platform

et al. 2022

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Current state-of-the-art stretchable/flexible sensors have received stringent demands on sensitivity, flexibility, linearity, and wide-range measurement capability. Herein, we report a methodology of strain sensors based on graphene/Ecoflex composites by modulating multiscale/hierarchical wrinkles on flexible substrates. The sensor shows an ultra-high sensitivity with a gauge factor of 1078.1, a stretchability of 650%, a response time of ~140 ms, and a superior cycling durability. It can detect wide-range physiological signals including vigorous body motions, pulse monitoring and speech recognition, and be used for monitoring of human respirations in real-time using a cloud platform, showing a great potential for the healthcare internet of things. Complex gestures/sign languages can be precisely detected. Human-machine interface is demonstrated by using a sensor-integrated glove to remotely control an external manipulator to remotely defuse a bomb. This study provides strategies for real-time/long-range medical diagnosis and remote assistance to perform dangerous tasks in industry and military fields.

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Conformal manufacturing of soft deformable sensors on the curved surface

Cited by 85 publications

References 170 publications

Asymmetrically Enhanced Coplanar‐Electrode Electroluminescence for Information Encryption and Ultrahighly Stretchable Displays

Asymmetrically Enhanced Coplanar‐Electrode Electroluminescence for Information Encryption and Ultrahighly Stretchable Displays

Developing the Nondevelopable: Creating Curved‐Surface Electronics from Nonstretchable Devices

Multiscale and hierarchical wrinkle enhanced graphene/Ecoflex sensors integrated with human-machine interfaces and cloud-platform

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