School of Advanced Materials Science & Engineering
Office Room # 25105 Buliding #25munjy@skku.edu
031-290-7354
Lab Website
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Education
2004.3 - 2010.9 Ph.D. in Department of Chemical Engineering, Seoul National University (Advisor: Prof. Seung M. Oh)
2000.3 – 2004.2 B.S. in Department of Chemical Engineering, Seoul National University
Experience
2022.2 - present Associate Professor, School of Advanced Materials Science & Engineering, SKKU
2013.8 – 2022.2 Assistant/Associate Professor, Department of Energy Chemical Engineering, Incheon National University
2010.9 – 2013.8 Research Staff, Samsung Advanced Institute of Technology
Research Interest
Active materials for cathode and anode in lithium ion batteries (Ni-rich, Li-rich, graphite and Si)
Safe rechargealbe batteries (All solid electrolyte batteries, & Aqueous electrolyte batteries)
Non-lithium ion batteries (Na, Mg, and Zn)
Electrolyte for rechargealbe batteries (solid electrolyte interface, redox flow batteries & room temperature ionic liquids)
Electrochemical study of metal in rechargeable batteries (high energy electrode, & corrosion)
Journal Articles
(2022) Reinforcement of Binder Adhesion for Nickel-Rich Layered Oxide in Lithium-ion Batteries using Perfluorinated Molecular Surface Modification. CHEMICAL ENGINEERING JOURNAL. 448, 137654.
(2022) Unraveling the Dynamic Interfacial behavior of LiCoO2 at Various Voltages with Lithium Bis(oxalato)borate for Lithium-Ion Batteries. ACS APPLIED MATERIALS & INTERFACES. 14, 10267-10276.
(2022) Crucial role of Ni-doping to interfacial Li2MnO3 layer of High-performance Ni-rich layered cathode in Lithium-Ion Batteries. CHEMICAL ENGINEERING JOURNAL. 434, 134577.
(2021) Mass-Scalable Molecular Monolayer for Ni-rich Cathode Powder: Solution for Microcrack Failure in Lithium-Ion Batteries. ACS APPLIED MATERIALS & INTERFACES. 13, 22475-22484.
(2021) Electrochemical corrosion behavior of iron in lithium-ion battery electrolyte. JOURNAL OF ELECTROCHEMICAL SCIENCE & TECHNOLOGY. 12, 424-430.
(2020) Structural and Thermodynamic Understandings in Mn-Based Sodium Layered Oxides during Anionic Redox. ADVANCED SCIENCE. 7, 2001263.
(2020) Crucial Role of Thioacetamide for ZrO2 Coating on the Fragile Surface of Ni-rich Layered Cathode in Lithium Ion Batteries. JOURNAL OF POWER SORCES. 450, 227625.
(2019) Aqueous lithium ion battery of nano-LiFePO4 with anti-freezing agent of ethyleneglycol for low temperature operation. ACS SUSTAINABLE CHEMISTRY & ENGINEERING. 7, 14531-14538.
(2018) Na+/vacancy disordered P2-Na0.67Co1-xTixO2: high energy and high power cathode materials for sodium ion batteries. ACS APPLIED MATERIALS & INTERFACES. 10, 3362-3570.
(2017) Egg-shell Structure LiCoO2 by Cu2+ Substitution to Li+ Site via Facile Stirring in an Aqueous Copper (II) Nitrate Solution. JOURNAL OF MATERIALS CHEMISTRY A. 5, 24892-24900.
(2017) Surface modification of the LiFePO4 cathode for the aqueous rechargeable lithium ion battery. ACS APPLIED MATERIALS & INTERFACES. 9, 12391-12399.
(2016) AlF3-coated LiMn2O4 as cathode material for aqueous rechargeable lithium battery with improved cycling stability. JOURNAL OF POWER SOURCES. 325, 360-364.
(2016) Surface Modification of Over-lithiated Layered Oxide by Low-Temperature Chemical Vapor Deposition for High Energy Lithium-ion Batteries. ENERGY STORAGE MATERIALS. 4, 137-144.
(2014) New dry carbon nanotube coating of over-lithiated layered oxide cathode for lithium ion battery. JOURNAL OF MATERIALS CHEMISTRY A. 2, 19670.
(2010) Comparative study on surface films from ionic liquids containing saturated and unsaturated substituent for LiCoO2. JOURNAL OF THE ELECTROCHEMICAL SOCIETY. 157, A136.