2004 | Alkyne oxidation by nonheme iron catalysts and hydroperoxides | 남원우; 김진흥 | Article |
2018 | Amphoteric reactivity of metal–oxygen complexes in oxidation reactions | 남원우; Shunichi Fukuzumi; 이용민 | Review |
2010 | An "End-On" chromium(III)-superoxo complex: Crystallographic and spectroscopic characterization and reactivity in C-H bond activation of hydrocarbons | 남원우; 조재흥 | Article |
2013 | An autocatalytic radical chain pathway in formation of an iron(iv)-oxo complex by oxidation of an iron(ii) complex with dioxygen and isopropanol | 남원우; Shunichi Fukuzumi; 이용민 | Article |
2003 | An FeIV=O complex of a tetradentate tripodal nonheme ligand | 남원우 | Article |
2009 | An iron(II) complex with a N3S2 thioether ligand in the generation of an iron(IV)-oxo complex and its reactivity in olefin epoxidation | 김성진; 남원우; 김영미; 서미숙; 이용민 | Article |
2014 | An isoelectronic NO dioxygenase reaction using a nonheme iron(iii)-peroxo complex and nitrosonium ion | 남원우; Kenneth D. Karlin | Article |
2002 | Anionic ligand effect on the nature of epoxidizing intermediates in iron porphyrin complex-catalyzed epoxidation reactions | 남원우 | Article |
2020 | Artificial nonheme iron and manganese oxygenases for enantioselective olefin epoxidation and alkane hydroxylation reactions | 남원우; Shunichi Fukuzumi | Review |
2001 | Augmented death in immunostimulated astrocytes deprived of glucose: Inhibition by an iron porphyrin FeTMPyP | 남원우 | Article |
2017 | Autocatalytic dioxygen activation to produce an iron(v)-oxo complex without any reductants | 남원우 | Article |
2014 | Autocatalytic formation of an iron(IV)-oxo complex via scandium ion-promoted radical chain autoxidation of an iron(II) complex with dioxygen and tetraphenylborate | 남원우; Shunichi Fukuzumi; 이용민 | Article |
2008 | Axial ligand effects on the geometric and electronic structures of nonheme oxoiron(IV) complexes | 남원우; 서미숙 | Article |
2005 | Axial ligand substituted nonheme FeIV=O complexes: Observation of near-UV LMCT bands and Fe=O Raman vibrations | 남원우; 김진흥; 서미숙 | Article |
2007 | Axial ligand tuning of a nonheme iron(IV)-oxo unit for hydrogen atom abstraction | 남원우; 김진흥 | Article |
1998 | Base specific complex formation of norfloxacin with DNA | 남원우 | Article |
2005 | Biochemistry: A thiolate-ligated nonheme oxoiron(IV) complex relevant to cytochrome P450 | 남원우 | Article |
2007 | Bioinspired chemical inversion of L-amino acids to D-amino acids | 남원우; 김관묵 | Article |
2001 | Biomimetic alkane hydroxylation by cobalt(III) porphyrin complex and m-chloroperbenzoic acid | 남원우; 김영미 | Article |
2021 | Biomimetic metal-oxidant adducts as active oxidants in oxidation reactions | 남원우; Shunichi Fukuzumi; 이용민; Mian Guo | Review |
2003 | Blockade of peroxynitrite-mediated astrocyte death by manganese(III)-cyclam | 남원우 | Article |
2022 | Bromoacetic Acid-Promoted Nonheme Manganese-Catalyzed Alkane Hydroxylation Inspired by α-Ketoglutarate-Dependent Oxygenases | 남원우; 이용민 | Article |
2013 | Brønsted acid-promoted C-H bond cleavage via electron transfer from toluene derivatives to a protonated nonheme iron(IV)-oxo complex with no kinetic isotope effect | 남원우; Shunichi Fukuzumi; 이용민 | Article |
2023 | Brønsted Acids Promote Olefin Oxidations by Bioinspired Nonheme CoIII(PhIO)(OH) Complexes: A Role for Low-Barrier Hydrogen Bonds | 남원우 | Article |
2012 | Catalytic four-electron reduction of O 2 via rate-determining proton-coupled electron transfer to a dinuclear cobalt-μ-1,2-peroxo complex | 남원우; Shunichi Fukuzumi; Antoni Llobet | Article |
2014 | Catalytic oxidation of alkanes by iron bispidine complexes and dioxygen: Oxygen activation versus autoxidation | 남원우; 이용민 | Article |
1996 | Catalytic oxygenation of alkenes and alkanes by oxygen donors catalyzed by cobalt-substituted polyoxotungstate | 남원우 | Article |
2012 | Chromium(IV)-peroxo complex formation and its nitric oxide dioxygenase reactivity | 남원우; 조재흥; Kenneth D. Karlin | Article |
2011 | Chromium(v)-oxo and chromium(iii)-superoxo complexes bearing a macrocyclic TMC ligand in hydrogen atom abstraction reactions | 남원우; 조재흥 | Article |
2012 | Cobalt analogs of Ru-based water oxidation catalysts: Overcoming thermodynamic instability and kinetic lability to achieve electrocatalytic O 2 evolution | 남원우; Antoni Llobet | Article |