Your search keyword '"Kim, Gwangmook"' showing total 6 results

1. Transparent and Flexible Graphene Pressure Sensor with Self-Assembled Topological Crystalline Ionic Gel.

Author

Kim, Kang Lib, Cho, Sung Hwan, Lee, Jae-Bok, Kim, Gwangmook, Lee, Kyuho, Lee, Seung Won, Kang, Han Sol, Park, Chanho, Ahn, Jong-Hyun, Shim, Wooyoung, Bae, Insung, and Park, Cheolmin

Published

2023

2. Transparent and Flexible Graphene Pressure Sensor with Self-Assembled Topological Crystalline Ionic Gel

Author

Kim, Kang Lib, Cho, Sung Hwan, Lee, Jae-Bok, Kim, Gwangmook, Lee, Kyuho, Lee, Seung Won, Kang, Han Sol, Park, Chanho, Ahn, Jong-Hyun, Shim, Wooyoung, Bae, Insung, and Park, Cheolmin

Abstract

This study demonstrates transparent and flexible capacitive pressure sensors using a high-kionic gel composed of an insulating polymer (poly(vinylidene fluoride-co-trifluoroethylene-co-chlorofluoroethylene), P(VDF-TrFE-CFE)) blended with an ionic liquid (IL; 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl) amide, [EMI][TFSA]). The thermal melt recrystallization of the P(VDF-TrFE-CFE):[EMI][TFSA] blend films develops the characteristic topological semicrystalline surface of the films, making them highly sensitive to pressure. Using optically transparent and mechanically flexible graphene electrodes, a novel pressure sensor is realized with the topological ionic gel. The sensor exhibits a sufficiently large air dielectric gap between graphene and the topological ionic gel, resulting in a large variation in capacitance before and after the application of various pressures owing to the pressure-sensitive reduction of the air gap. The developed graphene pressure sensor exhibits a high sensitivity of 10.14 kPa–1at 20 kPa, rapid response times of <30 ms, and durable device operation with 4000 repeated ON/OFF cycles. Furthermore, broad-range detections from lightweight objects to human motion are successfully achieved, demonstrating that the developed pressure sensor with a self-assembled crystalline topology is potentially suitable for a variety of cost-effective wearable applications.

Published

2023

3. Enhancing Li Ion Battery Performance by Mechanical Resonance

Author

Jin, Dana, Kang, Hyeonsoo, Do, Hyung Wan, Kim, Gwangmook, Kim, Taehoon, Kim, Sungsoon, Choi, Sangjin, Won, Jongbum, Park, Inchul, Jung, Keeyoung, and Shim, Wooyoung

Abstract

The quest for safe and high-performance Li ion batteries (LIBs) motivates intense efforts seeking a high-energy but reliable anode, cathode, and nonflammable electrolyte. For any of these, exploring new electrochemistry methods that enhance safety and performance by employing well-designed electrodes and electrolytes are required. Electrolyte wetting, governed by thermodynamics, is another critical issue in increasing Li ion transport through the separator. Herein, we report an approach to enhancing LIB performance by applying mechanical resonant vibration to increase electrolyte wettability on the separator. Wetting is activated at a resonant frequency with a capillary wave along the surface of the electrolyte, allowing the electrolyte to infiltrate into the porous separator by inertia force. This mechanical resonance, rather than electrochemistry, leads to the high specific capacity, rate capability, and cycling stability of LIBs. The concept of the mechanical approach is a promising yet simple strategy for the development of safer LIBs using liquid electrolytes.

Published

2021

4. Flexible artificial synesthesia electronics with sound-synchronized electroluminescence.

Author

Kim, Jong Sung, Cho, Sung Hwan, Kim, Kang Lib, Kim, Gwangmook, Lee, Seung Won, Kim, Eui Hyuk, Jeong, Beomjin, Hwang, Ihn, Han, Hyowon, Shim, Wooyoung, Lee, Tae-Woo, and Park, Cheolmin

Abstract

Abstract Visualization of human senses has been of great interest for developing an emerging interactive display that can artificially stimulate synesthesia with numerous unprecedented applications. Especially, visualization of various daily sound and music, which are much more complicated than human touch, in a form of flexible thin film devices can be a great challenge. We present flexible artificial synesthesia electronics that visualize continuous and complicated sounds. The electronic device is made of a thin composite film of a piezoelectric polymer for sound generation and inorganic electroluminescence (EL) microparticles for direct visualization of input sound signals. Field-induced EL of the microparticles in the device depends upon the source sound wave, making their EL synchronized with sound arising from the piezoelectric actuation. The flexible artificial synesthesia devices with sound-synchronized EL (FASSEL) showed extreme mechanical tolerance that can be repeatedly folded and crumpled with visible sound, allowing a variety of unexplored applications including synchronous sound-lightings and wearable, on-body sound-vision systems to facilitate emotional interaction of human being with sound in a human-friendly form. Graphical abstract Image 1 Highlights • Ultra-flexible piezoelectric loudspeakers were developed with sound synchronized EL. • Piezoelectric polymer composite with EL particles for direct visualization of sound. • Artificial synesthesia of sound and vision via a single capacitive device platform. • Silica-encapsulated-ZnS particle was employed for high EL with low leakage current. • Extreme mechanical tolerance that can be repeatedly folded and crumpled. [ABSTRACT FROM AUTHOR]

Published

2019

5. Flexible artificial synesthesia electronics with sound-synchronized electroluminescence

Author

Kim, Jong Sung, Cho, Sung Hwan, Kim, Kang Lib, Kim, Gwangmook, Lee, Seung Won, Kim, Eui Hyuk, Jeong, Beomjin, Hwang, Ihn, Han, Hyowon, Shim, Wooyoung, Lee, Tae-Woo, and Park, Cheolmin

Abstract

Visualization of human senses has been of great interest for developing an emerging interactive display that can artificially stimulate synesthesia with numerous unprecedented applications. Especially, visualization of various daily sound and music, which are much more complicated than human touch, in a form of flexible thin film devices can be a great challenge. We present flexible artificial synesthesia electronics that visualize continuous and complicated sounds. The electronic device is made of a thin composite film of a piezoelectric polymer for sound generation and inorganic electroluminescence (EL) microparticles for direct visualization of input sound signals. Field-induced EL of the microparticles in the device depends upon the source sound wave, making their EL synchronized with sound arising from the piezoelectric actuation. The flexible artificial synesthesia devices with sound-synchronized EL (FASSEL) showed extreme mechanical tolerance that can be repeatedly folded and crumpled with visible sound, allowing a variety of unexplored applications including synchronous sound-lightings and wearable, on-body sound-vision systems to facilitate emotional interaction of human being with sound in a human-friendly form.

Published

2019

6. Electroluminescent Pressure-Sensing Displays

Author

Lee, Seung Won, Cho, Sung Hwan, Kang, Han Sol, Kim, Gwangmook, Kim, Jong Sung, Jeong, Beomjin, Kim, Eui Hyuk, Yu, Seunggun, Hwang, Ihn, Han, Hyowon, Park, Tae Hyun, Jung, Seok-Heon, Lee, Jin Kyun, Shim, Wooyoung, and Park, Cheolmin

Abstract

Simultaneous sensing and visualization of pressure provides a useful platform to obtain information about a pressurizing object, but the fabrication of such interactive displays at the single-device level remains challenging. Here, we present a pressure responsive electroluminescent (EL) display that allows for both sensing and visualization of pressure. Our device is based on a two-terminal capacitor with six constituent layers: top electrode/insulator/hole injection layer/emissive layer/electron transport layer/bottom electrode. Light emission upon exposure to an alternating current field between two electrodes is controlled by the capacitance change of the insulator arising from the pressure applied on top. Besides capacitive pressure sensing, our EL display allows for direct visualization of the static and dynamic information of position, shape, and size of a pressurizing object on a single-device platform. Monitoring the pressurized area of an elastomeric hemisphere on a device by EL enables quantitative estimation of the Young’s modulus of the elastomer, offering a new and facile characterization method for the mechanical properties of soft materials.

Published

2024