사진

  • Scopus

An, Kwangjin (안광진)

Department
School of Energy and Chemical Engineering(에너지화학공학과)
Website
http://anlab.unist.ac.kr/
Lab
Advanced Nanocatalysis Lab. (첨단나노촉매 연구실)
Research Keywords
Nanocatalysis, Nanotechnology, Catalysis, Catalytic Process, C1 Gas Refinery, Biomass Conversion, Environmental Catalysis, Hydrogen Technology, Petrochemical process
Research Interests
Catalytic technology has been widely used in petrochemical processes to make not only oil, but also useful chemicals such as plastics, textiles and detergents. It is also used to remove emissions from cars and factories, and to clean and remove many environmentally harmful substances. Current catalyst technology is being developed to convert various renewable energy to be more efficient and to convert harmful environmental materials into useful. In the An Lab, we are developing catalysis technology that makes more valuable products from carbon dioxide and waste organic materials to solve the problems of global warming and environmental pollution.
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Issue DateTitleAuthor(s)TypeViewAltmetrics
2021-03Cu2O(100) surface as an active site for catalytic furfural hydrogenationLee, Jihyeon; Seo, Ji Hui; Nguyen-Huy, Chinh, et alARTICLE96 Cu2O(100) surface as an active site for catalytic furfural hydrogenation
2021-02Revealing Charge Transfer at the Interface of Spinel Oxide and Ceria during CO OxidationYoon, Sinmyung; Jo, Jinwoung; Jeon, Beomjoon, et alARTICLE14 Revealing Charge Transfer at the Interface of Spinel Oxide and Ceria during CO Oxidation
2021-02Atomically Alloyed Fe-Co Catalyst Derived from a N-Coordinated Co Single-Atom Structure for CO2 HydrogenationHwang, Sun-Mi; Han, Seung Ju; Park, Hae-Gu, et alARTICLE8 Atomically Alloyed Fe-Co Catalyst Derived from a N-Coordinated Co Single-Atom Structure for CO2 Hydrogenation
2021-01Modified Metal-Organic Frameworks as Efficient Catalysts for Lignocellulosic Biomass ConversionLee, Jun Gyeong; Nam, Eonu; An, KwangjinARTICLE21 Modified Metal-Organic Frameworks as Efficient Catalysts for Lignocellulosic Biomass Conversion
2020-12Al2O3-Coated Ni/CeO2 nanoparticles as coke-resistant catalyst for dry reforming of methaneEuiseob; Nam, Eonu; Lee, Jihyeon, et alARTICLE100 Al2O3-Coated Ni/CeO2 nanoparticles as coke-resistant catalyst for dry reforming of methane
2020-10Recycling Carbon Dioxide through Catalytic Hydrogenation: Recent Key Developments and PerspectivesRa, Eun Cheol; Kim, Kwang Young; Kim, Eun Hyup, et alARTICLE112 Recycling Carbon Dioxide through Catalytic Hydrogenation: Recent Key Developments and Perspectives
2020-10Structural evolution of ZIF-67-derived catalysts for furfural hydrogenationLee, Jun Gyeong; Yoon, Sinmyung; Yang, Euiseob, et alARTICLE57 Structural evolution of ZIF-67-derived catalysts for furfural hydrogenation
2020-08Cobalt Ferrite Nanoparticles to Form a Catalytic Co-Fe Alloy Carbide Phase for Selective CO2 Hydrogenation to Light OlefinsKim, Kwang Young; Lee, Hojeong; Noh, Woo Yeong, et alARTICLE98 Cobalt Ferrite Nanoparticles to Form a Catalytic Co-Fe Alloy Carbide Phase for Selective CO2 Hydrogenation to Light Olefins
2020-06Highly dispersed Pd catalysts supported on various carbons for furfural hydrogenationLee, Jihyeon; Woo, Jinwoo; Chinh Nguyen-Huy, et alARTICLE341 Highly dispersed Pd catalysts supported on various carbons for furfural hydrogenation
2020-03An efficient hydrogenation catalytic model hosted in a stable hyper-crosslinked porous-organic-polymer: from fatty acid to bio-based alkane diesel synthesisSarkar, Chitra; Shit, Subhash Chandra; Duy Quang Dao, et alARTICLE132 An efficient hydrogenation catalytic model hosted in a stable hyper-crosslinked porous-organic-polymer: from fatty acid to bio-based alkane diesel synthesis
2020-01Synergistic effect of quinary molten salts and Ruthenium catalyst for high-power-density Lithium-carbon dioxide cellBaek, Kyungeun; Jeon, Woo Cheol; Woo, Seongho, et alARTICLE339 Synergistic effect of quinary molten salts and Ruthenium catalyst for high-power-density Lithium-carbon dioxide cell
2019-08Structure-dependent catalytic properties of mesoporous cobalt oxides in furfural hydrogenationNguyen-Huy, Chinh; Lee, Jihyeon; Seo, Ji Hui, et alARTICLE433 Structure-dependent catalytic properties of mesoporous cobalt oxides in furfural hydrogenation
2019-06Integration of Interfacial and Alloy Effects to Modulate Catalytic Performance of Metal-Organic-Framework-Derived Cu-Pd Nanocrystals toward Hydrogenolysis of 5-HydroxymethylfurfuralSarkar, Chitra; Koley, Paramita; Shown, Indrajit, et alARTICLE320 Integration of Interfacial and Alloy Effects to Modulate Catalytic Performance of Metal-Organic-Framework-Derived Cu-Pd Nanocrystals toward Hydrogenolysis of 5-Hydroxymethylfurfural
2019-05Enhanced hot electron generation by inverse metal–oxide interfaces on catalytic nanodiodeLee, Hyosun; Yoon, Sinmyung; Jo, Jinwoung, et alARTICLE399 Enhanced hot electron generation by inverse metal–oxide interfaces on catalytic nanodiode
2019-04Catalytic 1-Propanol Oxidation on Size-Controlled Platinum Nanoparticles at Solid-Gas and Solid-Liquid Interfaces: Significant Differences in Kinetics and MechanismsLiu, Fudong; Han, Hui-Ling; Carl, Lindsay M., et alARTICLE467 Catalytic 1-Propanol Oxidation on Size-Controlled Platinum Nanoparticles at Solid-Gas and Solid-Liquid Interfaces: Significant Differences in Kinetics and Mechanisms
2019-02Mesoporous mixed CuCo oxides as robust catalysts for liquid-phase furfural hydrogenationNguyen-Huy, Chinh; Lee, Hojeong; Lee, Jihyeon, et alARTICLE570 Mesoporous mixed CuCo oxides as robust catalysts for liquid-phase furfural hydrogenation
2018-12SiO2@V2O5@Al2O3 core-shell catalysts with high activity and stability for methane oxidation to formaldehydeYang, Euiseob; Lee, Jun Gyeong; Kim, Dong Hyeon, et alARTICLE550 SiO2@V2O5@Al2O3 core-shell catalysts with high activity and stability for methane oxidation to formaldehyde
2018-12Catalytic CO Oxidation over Au Nanoparticles Supported on CeO2 Nanocrystals: Effect of the Au-CeO2 InterfaceHa, Hyunwoo; Yoon, Sinmyung; An, Kwangjin, et alARTICLE492 Catalytic CO Oxidation over Au Nanoparticles Supported on CeO2 Nanocrystals: Effect of the Au-CeO2 Interface
2018-10Chemically impregnated NiO catalyst for molten electrolyte based Gas-tank-free Li-O2 batteryBaek, Kyungeun; Lee, Jun Gyeong; Cha, Aming, et alARTICLE693 Chemically impregnated NiO catalyst for molten electrolyte based Gas-tank-free Li-O2 battery
2018-08Supported Pd nanoparticle catalysts with high activities and selectivities in liquid-phase furfural hydrogenationNguyen-Huy, Chinh; Kim, Ji Sun; Yoon, Sinmyung, et alARTICLE855 Supported Pd nanoparticle catalysts with high activities and selectivities in liquid-phase furfural hydrogenation

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