Studying chemistry in cyberspace

Abstract

Jun-Hyeong earned his BS degree in physics and chemistry from Ulsan National Institute of Science and Technology (UNIST). He later moved to Korea Advanced Institute of Science and Technology (KAIST) to obtain a PhD degree in chemistry under the guidance of Prof. Mu-Hyun (Mookie) Baik. During his PhD studies, he focused on gaining a quantitative understanding of the electronic structure of redox non-innocent ligands using multiconfigurational methods. He is now expanding his research area to developing density functional methods for the electro-inductive effect, namely fractional charge density functional theory (DFT). Jun-Hyeong earned his BS degree in physics and chemistry from Ulsan National Institute of Science and Technology (UNIST). He later moved to Korea Advanced Institute of Science and Technology (KAIST) to obtain a PhD degree in chemistry under the guidance of Prof. Mu-Hyun (Mookie) Baik. During his PhD studies, he focused on gaining a quantitative understanding of the electronic structure of redox non-innocent ligands using multiconfigurational methods. He is now expanding his research area to developing density functional methods for the electro-inductive effect, namely fractional charge density functional theory (DFT). Photodynamic treatment of acute vascular occlusion by using an iron–nitrosyl complexChoe et al.ChemMarch 15, 2023In BriefSpatiotemporally controllable nitric oxide transporter, iron–nitrosyl complex, was synthesized and precisely characterized by various physicochemical methods, including X-ray crystallography, together with quantum chemical calculations. Normal retinal blood vessels were expanded by the photoreactive iron–nitrosyl complex. Occluded retinal vessels were effectively reperfused by nitric oxide released from the iron–nitrosyl complex via photoreaction in animal disease models. Our strategy demonstrates potential in the treatment option for acute vascular occlusive diseases. Full-Text PDF Open Access