강준구
Kang, JoongooDepartment of Physics and Chemistry
학력
- 2003 ~ 2007한국과학기술원 박사
- 2001 ~ 2003한국과학기술원 석사
- 1997 ~ 2001한국과학기술원 학사
경력
- 2010 ~ 2014National Renewable Energy Lab / 선임연구원
- 2008 ~ 2010National Renewable Energy Lab / 연구원
- 2007 ~ 2008자연과학연구소 / 연구원
수상실적
연구실 소개
- Computational Materials Theory Group
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The Computational Materials Theory Group, led by Professor Joongoo Kang, develops predictive frameworks that marry quantum mechanics, atomic-scale simulations, and machine learning to design functional materials from first principles. Our work in materials-by-design applies quantum-mechanical theory to tailor electronic, optical, and thermal properties for energy conversion and information technologies. By integrating machine-learned interatomic potentials, we uncover new physics and chemistry in complex materials systems—studying structures and dynamics beyond human intuition. In the realm of simple complexity, we employ ML-driven statistical physics and enhanced sampling methods such as metadynamics to reveal how liquids, glasses, and other disordered systems emerge from simple physical laws. Together, these approaches establish a materials-by-design paradigm that bridges fundamental theory and practical applications.
Related Keyword
- "Targeted Selenite Adsorption Using Defective Fe-BTC: Effective in Acidic and Alkaline Conditions", Small, v.21, no.37
- "Molecular Surface Doping of Cellulose Nanocrystals: A High-Throughput Computational Study", Lee, Juhyung. (2024-11). Molecular Surface Doping of Cellulose Nanocrystals: A High-Throughput Computational Study. Chemistry of Materials, 36(23), 11421–11431. doi: 10.1021/acs.chemmater.4c02045
- "Radical-Driven Crystal-Amorphous-Crystal Transition of a Metal-Organic Framework", Park, Seonghun. (2024-03). Radical-Driven Crystal-Amorphous-Crystal Transition of a Metal-Organic Framework. Journal of the American Chemical Society, 146(13), 9293–9301. doi: 10.1021/jacs.4c01040
- "Unveiling the Nanocluster Conversion Pathway for Highly Monodisperse InAs Colloidal Quantum Dots", Shin, Jibin. (2024-02). Unveiling the Nanocluster Conversion Pathway for Highly Monodisperse InAs Colloidal Quantum Dots. JACS Au, 4(3), 1097–1106. doi: 10.1021/jacsau.3c00809
- "Identifying and clearing individual oxygen impurities on graphene through the use of NO2 as a radical scavenger", Lee, Juhyung. (2023-11). Identifying and clearing individual oxygen impurities on graphene through the use of NO2 as a radical scavenger. Carbon, 215. doi: 10.1016/j.carbon.2023.118490