Advanced Nanocatalysis Lab

첨단나노촉매 연구실

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첨단나노촉매 연구실

촉매 기술은 석유뿐만 아니라 플라스틱, 섬유 및 세제와 같은 유용한 화학 물질을 만들기 위해 석유 화학 공정에서 널리 사용되고 있습니다. 또한 자동차 및 공장에서 배출되는 가스를 제거하고 환경 유해 물질을 정화하고 및 제거하는데 사용됩니다. 현재의 촉매 기술은 다양한 재생 에너지를 보다 효율적으로 변환하고, 유해한 환경 물질을 유용한 화학물질로 변환시키기 위해 지속적으로 개발되고 있습니다. 저희 An Lab에서는 나노기술을 바탕으로 지구 온난화 및 환경오염 문제를 해결하기 위해 이산화탄소, 유기 폐기물 및 폐플라스틱 등을 귀중한 제품으로 만드는 첨단의 촉매 기술 을 개발하고 있습니다.
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, organic wastes, and post-consumer plastics to solve the problems of global warming and environmental pollution.

Major research field

Nanotechnology, Catalysis, Environment, Chemical Process, Biomass Conversion, Upgrading

Desired field of research

Single Atom Catalysis, Environmental Catalysis, Plastic Upcycling, Removal of Volatile Organic Compounds

Research Keywords and Topics

• Nanocatalysis: Size and Shape Effects, Strong Metal Support Interaction, Single-Atom Catalyst, In situ Characterizations
• Carbon Neutrality: CO Oxidation, CO2 Conversion (GTL, Fischer-Tropsch), CH4- Conversion (to HCHO, DRM..), CH4 to H2 and Carbon (CNT synthesis)
• Biomass Conversion: Lignin Valorization, Green Plastics, H2-Fee Hydrodeoxygenation
• Plastic Up-cycling : Hydrogenolysis of PE and PP, PET glycolysis, Pyrolysis
• Hydrogen Technology : Liquid Organic Hydrogen Carrier (LOHC), Hydrogen Production via Methane Reforming, Ammonia Decomposition
• Petrochemical process: Production of Linear Alpha-Olefins, Reductive Hydroformylation, Heavy Oil Upgrading

Research Publications
MORE

• ACS CATALYSIS / Revealing Charge Transfer at the Interface of Spinel Oxide and Ceria during CO Oxidation / Yoon, Sinmyung; Jo, Jinwoung; Jeon, Beomjoon; Lee, Jihyeon; Cho, Min Gee; Oh, Myoung Hwan; Jeong, Beomgyun; Shin, Tae Joo; Jeong, Hu Young; Park, Jeong Young; Hyeon, Taeghwan; An, Kwangjin / 2021-01
• JOURNAL OF CATALYSIS / SiO2@V2O5@Al2O3 core-shell catalysts with high activity and stability for methane oxidation to formaldehyde / Yang, Euiseob; Lee, Jun Gyeong; Kim, Dong Hyeon; Jung, Yoon Seok; Kwak, Ja Hun; Park, Eun Duck; An, Kwangjin / 2018-12
• ACS CATALYSIS / Specific Metal-Support Interactions between Nanoparticle Layers for Catalysts with Enhanced Methanol Oxidation Activity / Yoon, Sinmyung; Oh, Kyunghwan; Liu, Fudong; Seo, Ji Hui; Somorjai, Gabor A.; Lee, Jun Hee; An, Kwangjin / 2018-06

국가과학기술표준분류

  • EC. 화공
  • EC01. 화학공정
  • EC0101. 촉매/반응기술

국가기술지도분류

  • 환경/에너지 프론티어 진흥
  • 031400. 에너지 절약형 반응 및 분리공정기술

녹색기술분류

  • 고효율화기술
  • 친환경 제조공정 및 소재효율성 향상
  • 354. 친환경 공정 및 제품 기타 기술

6T분류

  • ET 분야
  • 에너지
  • 050213. 고효율 반응분리공정기술