Prof Choong-Gon LEE , Hanbat National University, South Korea
Publication Profile
Scopus
Academic Background π
Professor Choong-Gon LEE received his Ph.D. in Applied Chemistry from Tohoku University, Japan, in 1997. Prior to this, he earned his M.S. in Chemical Engineering in 1988 and his B.S. in Chemical Engineering in 1986, both from Yonsei University, Korea.
Professional Experience π¨βπ«
Since 2004, Professor LEE has been a distinguished faculty member at Hanbat National University. In his role, he has been dedicated to teaching electrochemical engineering and conducting groundbreaking research in the field of electrochemistry. His primary focus areas include fuel cells and hydrogen production, where he has made significant contributions to the advancement of sustainable energy solutions.
Research Focus
Professor Choong-Gon LEE specializes in the field of electrochemical engineering, with a strong focus on sustainable energy solutions. His research encompasses the production of hydrogen (H2) and sodium hydroxide (NaOH) from alkaline solutions containing carbon dioxide (CO2) using cation exchange membranes. He also investigates the effects of temperature on electrode reactions in molten carbonate and solid oxide fuel cells, aiming to enhance their efficiency and performance. Professor LEE’s work is notable for its practical applications, such as developing methods for electrochemical hydrogen production utilizing captured CO2. His collaborative efforts with researchers and industry partners highlight his commitment to advancing electrochemical science and environmental sustainability. Through his numerous publications in high-impact journals, Professor LEE contributes significantly to the understanding and innovation in the fields of fuel cells, electrolysis, and carbon recycling. His research not only advances scientific knowledge but also addresses critical challenges in sustainable energy production. π±ππ
“Electrolytic production of NaOH and H2 from alkaline solution containing CO2 using cation exchange membranes” (2024) – 0 citations π±
“Effect of temperature on the electrode overpotential of molten carbonate electrolysis and fuel cells with inert-gas step addition method” (2023) – 0 citations π‘οΈ
“Effect of temperature on the electrode reactions in a planar solid oxide fuel cell” (2023) – 0 citations π
“Reaction characteristics of molten carbonate cell operated in fuel cell and electrolysis modes with reactant gas addition method” (2023) – 0 citations β‘
“Electrochemical hydrogen production using captured CO2 in alkaline solution” (2023) – 3 citations π§
“Comparison of gas phase transport effects between fuel cell and electrolysis cell modes of a 100 cm2 class molten carbonate cell” (2022) – 2 citations π
“Electrode reaction properties using a reactant gas addition method in a commercial 100 cm2 class solid oxide fuel cell” (2022) – 4 citations π
“Experimental analysis of internal leakage current using a 100 cm2 class planar solid oxide fuel cell” (2021) – 4 citations π
“Lifetime expectancy of molten carbonate fuel cells: Part II. Cell life simulation using bench and coin-type cells” (2021) – 3 citations β³
“Lifetime Expectancy of molten carbonate fuel cells: Part I. Effect of temperature on the voltage and electrolyte reduction rates” (2021) – 4 citations π₯