40.
Hybrid-Structured Indium Tin Oxide with Ag Nanoparticles as Crystalline Seeds for Transparent Electrode with Enhanced Flexibility and Its Application to Organic Light Emitting Diodes
Japanese Journal of Applied Physics, May 2014, Volume 53, Issue 5S1, 05FB13
Ross E. Triambulo, Hahn-Gil Cheong, Huanyu Zhou, Gun-Hwan Lee and Jin-Woo Park
39.
The effect of the size and volume fraction of Zr2Cu on the sintering behavior of tungsten matrix composites during liquid-reactive sintering
International Jounal of Refractory Metals and Hard Materials, March 2014, Volume 43, p.157-163
Jin-Woo Park, Ji-Yeon Suh, Seung-Won Kang, Se-Eun Shin, Dong-Hyun Bae
32.
The effect of alloy compositions on the microstructure and the mechanical strength of oxide scales on four selected steels
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, Volume 556, October 2012, 246–252
Chan-Woo Yang, Seung-Mok Cho, Youn-Hee Kang , Jong-Sub Lee, Jin-Woo Park
40.
Hybrid-Structured Indium Tin Oxide with Ag Nanoparticles as Crystalline Seeds for Transparent Electrode with Enhanced Flexibility and Its Application to Organic Light Emitting Diodes
Japanese Journal of Applied Physics, May 2014, Volume 53, Issue 5S1, 05FB13
Ross E. Triambulo, Hahn-Gil Cheong, Huanyu Zhou, Gun-Hwan Lee and Jin-Woo Park
39.
The effect of the size and volume fraction of Zr2Cu on the sintering behavior of tungsten matrix composites during liquid-reactive sintering
International Jounal of Refractory Metals and Hard Materials, March 2014, Volume 43, p.157-163
Jin-Woo Park, Ji-Yeon Suh, Seung-Won Kang, Se-Eun Shin, Dong-Hyun Bae
32.
The effect of alloy compositions on the microstructure and the mechanical strength of oxide scales on four selected steels
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, Volume 556, October 2012, 246–252
Chan-Woo Yang, Seung-Mok Cho, Youn-Hee Kang , Jong-Sub Lee, Jin-Woo Park
Research area
LMI investigates interfaces between dissimilar materials at nano to macro-scale. We develop experimental and computational approaches towards understanding the fundamentals of the interfaces - physical and chemical properties of interfaces, interface formation mechanisms, and changes in mechanical / functional status of materials systems by forming interfaces. Our insights are the basis for designing newly engineered materials and advanced engineering systems.
LMI's current research efforts are focused on exploring broad areas of current and promising wearable systems including energy harvesting/storage, sensors/actuators, and integrated circuits and devices that consist of enormous ranges of dissimilar materials interfaces systems. The applications of the wearable technology could include continuously monitor diseases and particular chemicals such as glucose in blood; track physical and environment conditions for workers and athletes; and even improve surveillance and gaming.
