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Your search keyword '"Shin, Kwang-Ho"' showing total 114 results
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114 results on '"Shin, Kwang-Ho"'

1. Mechanical‐Stress‐Induced Lithiation and Structural Evolution Driven by Excess Lithium Predisposing Short Circuits at the Surface of Garnet Solid Electrolytes.

Author

Hong, Seokjae, Shin, Kwang Ho, Kim, Seulgi, Song, Seok Hyun, Kim, Kyoung Sun, Lee, Dongju, Yu, Seung‐Ho, Jung, Sung‐Kyun, and Kim, Hyungsub

Subjects
*PHASE transitions, *SOLID electrolytes, *SURFACE strains, *INTERFACIAL resistance, *STRAINS & stresses (Mechanics), *SUPERIONIC conductors, *IONIC conductivity
Abstract

Cubic‐garnet solid electrolyte has garnered significant attention in all‐solid‐state batteries (ASSBs) due to its ionic conductivity and chemical robustness against Li metal. However, the short‐circuit formation at low current density poses a significant obstacle with the main cause remaining ambiguous. Here, the lithium‐penetration mode originating from phase transformation is unveiled at the sintered pellet surface via mechanically induced lithiation. Mechanical stress applied during polishing under excess lithium content induces lithiation into the cubic‐garnet structure, leading to partial structural evolution into the tetragonal phase. This surface alteration induces current constriction, hindered by sluggish interfacial Li‐ion transport from the tetragonal phase, which exhibits low ionic conductivity, causing short circuits. By reducing mechanical stress, mitigating surface strain, and restoring the cubic phase, stable operation is ensured without short‐circuit formation in both Li symmetric and hybrid‐full cells. This insights illuminate the origin of lithium penetration related to phase transition at the surface of cubic‐garnet and pave the way for enhancements in ASSB development. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Magnetoresistive Sensor Development Roadmap (Non-Recording Applications)

Author

Zheng, Chao, primary, Zhu, Ke, additional, Cardoso de Freitas, Susana, additional, Chang, Jen-Yuan, additional, Davies, Joseph E., additional, Eames, Peter, additional, Freitas, Paulo P., additional, Kazakova, Olga, additional, Kim, CheolGi, additional, Leung, Chi-Wah, additional, Liou, Sy-Hwang, additional, Ognev, Alexey, additional, Piramanayagam, S. N., additional, Ripka, Pavel, additional, Samardak, Alexander, additional, Shin, Kwang-Ho, additional, Tong, Shi-Yuan, additional, Tung, Mean-Jue, additional, Wang, Shan X., additional, Xue, Songsheng, additional, Yin, Xiaolu, additional, and Pong, Philip W. T., additional

Published
2019
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21. AC permeability of Fe-Co-Ge/WC/phenol magnetostrictive composites

Author

Shin, Kwang-Ho, Kim, Younghak, and Lim, Sang-Ho

Subjects
Alternating current -- Research, Germanium -- Magnetic properties, Germanium -- Electric properties, Iron compounds -- Magnetic properties, Iron compounds -- Electric properties, Business, Electronics, Electronics and electrical industries
Abstract

Polymer-bonded magnetostrictive composites of flake-type Fe-Co-Ge powder were fabricated and their complex permeability were characterized in the frequency range of 100-100 kHz using the modified ferrite core method. This alternating current (ac) permeability measurement method is firstly proposed in this study, and has some merits, such as easy handling and stress-free measuring. The WC powder, as a highly elastic material, with various amount of 0 wt%-30 wt% was added to form magnetostrictive composite to investigate high-frequency magnetic properties with measured permeability. The real part of permeability is almost constant with frequency varying. Also, the imaginary part of permeability increases exponentially with frequency increase. Both real and imaginary parts of permeability decrease with WC content increase to 20 wt%, but the composite of 30 wt% WC has larger permeability than that of 20 wt%. Index Terms--Alternating current (ac) permeability, magnetostrictive composite, stress-free measurement.

Published
2005

22. Strain sensitivity of highly magnetostrictive amorphous films for use in microstrain sensors

Author

Shin, Kwang-Ho, Inoue, Mitsuteru, and Arai, Ken-Ichi

Subjects
Thin films -- Research, Amorphous substances -- Research, Strains and stresses -- Research, Physics
Abstract

A study was conducted on the strain sensitivity of amorphous (Fe(sub 90)Co(sub 10))(sub 78)Si(sub12)B(sub 10) sputtered film to examine its potential for highly sensitive microstrain gauges. Results showed that the films had very high sensitivity to strain. It was found that the magnetic uniaxial anisotropy of the film is the key parameter which governs the strain sensitivity of the film where the induction of clear but small anisotropy is needed for achieving the high sensitivity to strain.

Published
1999

24. Anisotropy Control of Magnetostrictive Film Patterns

Author

Imamura, Kouki, Shin, Kwang-Ho, Ishiyama, Kazushi, Inoue, Mitsuteru, and Arai, Ken Ichi

Subjects
Magnetoresistance -- Research, Thin films -- Magnetic properties, Business, Electronics, Electronics and electrical industries
Abstract

The magnetic properties of Fe-based amorphous films are thought to be highly sensitive to strain due to the large saturation magnetostriction and soft magnetic properties exhibited by the films. This is why patterned FeCoSiB films exhibit a large variation in their high-frequency impedance when strain is applied. To increase the sensitivity of strain sensors, it is very important to control the magnitude of magnetic anisotropy. We propose a method to control the magnetic anisotropy by stress bias annealing. By applying stress during annealing, we were able to control the anisotropy along the width of the patterned film. A strain sensor using a transverse-anisotropy-induced film pattern exhibited a figure of merit F [approximately equals] 8300, while a sensor without anisotropy exhibited the F of only 500. Index Terms--Anisotropy control, high-frequency impedance, magnetostrictive film, strain sensitivity.

Published
2001

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