Yong Whan Choi scite author profile

Recently developed flexible mechanosensors based on inorganic silicon, organic semiconductors, carbon nanotubes, graphene platelets, pressure-sensitive rubber and self-powered devices are highly sensitive and can be applied to human skin. However, the development of a multifunctional sensor satisfying the requirements of ultrahigh mechanosensitivity, flexibility and durability remains a challenge. In nature, spiders sense extremely small variations in mechanical stress using crack-shaped slit organs near their leg joints. Here we demonstrate that sensors based on nanoscale crack junctions and inspired by the geometry of a spider's slit organ can attain ultrahigh sensitivity and serve multiple purposes. The sensors are sensitive to strain (with a gauge factor of over 2,000 in the 0-2 per cent strain range) and vibration (with the ability to detect amplitudes of approximately 10 nanometres). The device is reversible, reproducible, durable and mechanically flexible, and can thus be easily mounted on human skin as an electronic multipixel array. The ultrahigh mechanosensitivity is attributed to the disconnection-reconnection process undergone by the zip-like nanoscale crack junctions under strain or vibration. The proposed theoretical model is consistent with experimental data that we report here. We also demonstrate that sensors based on nanoscale crack junctions are applicable to highly selective speech pattern recognition and the detection of physiological signals. The nanoscale crack junction-based sensory system could be useful in diverse applications requiring ultrahigh displacement sensitivity.

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Ultra-flexible perovskite solar cells with crumpling durability: toward a wearable power source

Lee

Kim

Choi

et al. 2019

Energy Environ. Sci.

143

186

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Ultra-sensitive Pressure sensor based on guided straight mechanical cracks

Choi

Kang

Pikhitsa

et al. 2017

Sci Rep

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Recently, a mechanical crack-based strain sensor with high sensitivity was proposed by producing free cracks via bending metal coated film with a known curvature. To further enhance sensitivity and controllability, a guided crack formation is needed. Herein, we demonstrate such a ultra-sensitive sensor based on the guided formation of straight mechanical cracks. The sensor has patterned holes on the surface of the device, which concentrate the stress near patterned holes leading to generate uniform cracks connecting the holes throughout the surface. We found that such a guided straight crack formation resulted in an exponential dependence of the resistance against the strain, overriding known linear or power law dependences. Consequently, the sensors are highly sensitive to pressure (with a sensitivity of over 1 × 105 at pressures of 8–9.5 kPa range) as well as strain (with a gauge factor of over 2 × 106 at strains of 0–10% range). A new theoretical model for the guided crack system has been suggested to be in a good agreement with experiments. Durability and reproducibility have been also confirmed.

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Highly durable crack sensor integrated with silicone rubber cantilever for measuring cardiac contractility

Kim¹,

Choi²,

Jeong³

et al. 2020

Nat Commun

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We propose a novel cantilever device integrated with a polydimethylsiloxane (PDMS)encapsulated crack sensor that directly measures the cardiac contractility. The crack sensor was chemically bonded to a PDMS thin layer to form a sandwiched structure which allows to be operated very stably in culture media. The reliability of the proposed crack sensor has improved dramatically -2-compared to no encapsulation layer. After evaluating the durability of the crack sensor bonded with the PDMS layer, cardiomyocytes were cultured on the nano-patterned cantilever for real-time measurement of cardiac contractile forces. The highly sensitive crack sensor continuously measured the cardiac contractility without changing its gauge factor for up to 26 days (>5 million heartbeats). In addition, changes in contractile force induced by drugs were monitored using the crack sensorintegrated cantilever. Finally, experimental results were compared with those obtained via conventional electrophysiological methods to verify the feasibility of building a contraction-based drug-toxicity testing system.

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Transparent ITO mechanical crack-based pressure and strain sensor

et al. 2016

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Shape‐Controllable Microlens Arrays via Direct Transfer of Photocurable Polymer Droplets

et al. 2012

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Facile Multiscale Patterning by Creep-Assisted Sequential Imprinting and Fuel Cell Application

Jang¹,

Kim

Kang

et al. 2016

ACS Appl. Mater. Interfaces

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The capability of fabricating multiscale structures with desired morphology and incorporating them into engineering applications is key to realizing technological breakthroughs by employing the benefits from both microscale and nanoscale morphology simultaneously. Here, we developed a facile patterning method to fabricate multiscale hierarchical structures by a novel approach called creep-assisted sequential imprinting. In this work, nanopatterning was first carried out by thermal imprint lithography above the glass transition temperature (Tg) of a polymer film, and then followed by creep-assisted imprinting with micropatterns based on the mechanical deformation of the polymer film under the relatively long-term exposure to mechanical stress at temperatures below the Tg of the polymer. The fabricated multiscale arrays exhibited excellent pattern uniformity over large areas. To demonstrate the usage of multiscale architectures, we incorporated the multiscale Nafion films into polymer electrolyte membrane fuel cell, and this device showed more than 10% higher performance than the conventional one. The enhancement was attributed to the decrease in mass transport resistance because of unique cone-shape morphology by creep-recovery effects and the increase in interfacial surface area between Nafion film and electrocatalyst layer.

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Crack-based strain sensor with diverse metal films by inserting an inter-layer

et al. 2017

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Yong Whan Choi

Ultrasensitive mechanical crack-based sensor inspired by the spider sensory system

Ultra-flexible perovskite solar cells with crumpling durability: toward a wearable power source

Ultra-sensitive Pressure sensor based on guided straight mechanical cracks

Highly durable crack sensor integrated with silicone rubber cantilever for measuring cardiac contractility

Transparent ITO mechanical crack-based pressure and strain sensor

Shape‐Controllable Microlens Arrays via Direct Transfer of Photocurable Polymer Droplets

Facile Multiscale Patterning by Creep-Assisted Sequential Imprinting and Fuel Cell Application

Crack-based strain sensor with diverse metal films by inserting an inter-layer

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