Hanyang University | South Korea
Mr. Jinmyeong Seo is a dedicated researcher in the field of materials science and chemical engineering with strong expertise in electrochemical synthesis and device fabrication. He earned his Bachelor, Master, and is currently pursuing his Ph.D. in Materials Science and Chemical Engineering at Hanyang University, South Korea, under the guidance of Prof. Bongyoung Yoo. His master’s research focused on the electrochemical behavior of protons in silicon dioxide, laying a solid foundation for his current doctoral work. His research interests center on the synthesis of thin films and nanomaterials, including metals, metal oxides, and metal chalcogenides, primarily through electrochemical deposition. He is actively engaged in chalcogenide thin film transistor (TFT) device fabrication, NO₂ gas sensor development using electrodeposited ZnTe, advanced packaging technologies such as Cu-Cu bonding and TSV filling, and the synthesis of carbon-metal composites for applications like PEMFC bipolar plates. Seo possesses advanced experimental skills in deposition methods, device fabrication, and material characterization, including electrochemical, electrical, and mechanical testing techniques, as well as semiconductor processing. His contributions reflect a commitment to bridging fundamental materials research with practical applications in electronics, sensors, and energy systems. He continues to pursue impactful research that supports technological innovation and sustainable development in materials science.
Featured Publications
Electrochemical Pathway-Controlled Growth of Tellurium Nanostructures on a Nonconductive Substrate
Electrochemical Synthesis of Tellurium Nanostructure on Non-Conductive Substrate by Redox Reaction of Tellurium Ions
Electrodeposition of Ru on Nanoscale Trench Patterns
Uniformly dispersed ruthenium nanoparticles on porous carbon from coffee waste outperform platinum for hydrogen evolution reaction in alkaline media
Electrodeposition of Nickel-Tungsten Alloy with Functional Concentration Periodically Graded Material Structure for Low Stress and High Hardness
Electrodeposition of stress-relaxation-induced (111)-oriented nanotwin copper film by direct current in additive-free electrolyte
3-D Nanostructure Palladium Synthesis By Electrochemical Deposition for Hydrogen Sensor with Switching Resistance Characteristic in Normal Temperature and Pressure