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Copyright@Beijing University of Chemical Technology Address: 15 Beisanhuan East Road, Chaoyang District, Beijing, China Zip code:100029 Email:news@buct.edu.cn |
IntroductionEducation: 1、Doctor of Engineering, Chemical Engineering, Dalian Institute of Chemical Physics, Chinese Academy of Sciences , May 2015. 2、Bachelors of Chemical Engineering/Administration, Chemical Engineering and Technology /Business Administration, Harbin Engineering University, June 2010. Research Experience: July 2015 – present: Associate Professor, College of Chemical Engineering, Beijing University of Chemical Technology (BUCT, China). EducationWork ExperienceSocial PositionSocial ActivitiesResearch1、Design, synthesis, characterization and application of energy materials (carbon-based materials, MOF, COP, metal compound and so on). 2、Catalytic and electrocatalytic process and their mechanism (ORR, HER, Insertion/Extraction Redox of surface and dynamics). 3、reparation and scale-up of energy conversion and storage devices, including fuel cells, water splitting, lithium batteries (lithium ion batteries, lithium sulfur batteries and lithium-air batteries), supercapacitors, solar cells and so on. Teaching1、Principles of Chemical Engineering 2、Experiment of Chemical Engineering Principle PostgraduatesFundingRepresentative research projects are as follows: 1. National Natural Science Foundation Project; 2. Beijing Natural Science Foundation Project; 3. National frontier innovation projects; 4. Several horizontal projects of central enterprises such as State Power Investment, National Energy Group and Aerospace Science and Technology Group. Vertical ProjectHorizontal ProjectPublicationsRecent Publications: 1. A Double-ligand Chelating Strategy to Iron Complex Anolytes with Ultrahigh Cyclability for Aqueous Iron Flow Batteries,Angewandte Chemie International Edition,2024,63,e3202316593. 2. A Bifunctional Liquid Fuel Cell Coupling Power Generation and V3.5+ Electrolytes Production for All Vanadium Flow Batteries,Advanced Science,2023,18,202207728. 3. Double Riveting and Steric Hindrance Strategy for Ultrahigh-Loading Atomically Dispersed Iron Catalysts Toward Oxygen Reduction,Small,2023,33,202301456. 4. Atomically Dispersed Iron with Densely Exposed Active Sites as Bifunctional Oxygen Catalysts for Zinc–Air Flow Batteries. Small, 2022, 18, 2105892. 5. Semi-solid zinc slurry with abundant electron-ion transfer interfaces for aqueous zinc-based flow batteries,Journal of Power Sources,2022,535,231442 6. Low-cost carbon derived from coal-coke for high performance supercapacitors, Journal of Electroanalytical Chemistry,2022,921,116678 7. Bimetal-phthalocyanine based covalent organic polymers for highly efficient oxygen electrode. Applied Catalysis B: Environmental,2019, 243, 204-211. 8. In situ growing catalytic sites on 3D carbon fiber paper as self-standing bifunctional air electrodes for air-based flow batteries.Nano Energy,2019.63,103897. 9. Efficient unitary oxygen electrode for air-based flow batteries.Nano Energy,2018, 47, 361-367. 10. A long-life hybrid zinc flow battery achieved by dual redox couples at cathode. Nano Energy, 2019, 63,103822. 11. Ultrastable Hydrogen Evolution Electrocatalyst Derived from Phosphide Post-modified Metal-Organic Frameworks. Nano Energy, 2017, 35, 115-120. 12. Hierarchically porous metal-free carbon with record high mass activity for oxygen reduction and Zn-air batteries. Journal of Materials Chemistry A, 2019, 7, 9831. 13. Bifunctional oxygen electrodes with gradient hydrophilic/hydrophobic reactive interfaces for metal air flow batteries, Chemical Engineering Science, 2020, 224, 115795. 14. Interface modification of electrodes through polyethylene glycol in rechargeable zinc-nickel batteries, Chemical Engineering Science, 2021, 232, 116372. 15. Semi-solid reactive interfaces based on ZnO@C core-shell materials for zinc-iron flow batteries, Chemical Engineering Science, 2022, 250, 117402. 16. Confined Space Assisted Preparation of Fe3O4 Nanoparticles Modified Fe-N-C Catalysts derived from Covalent Organic Polymer for Oxygen Reduction., ACS Sustainable Chemistry & Engineering, 2017, 5, 7871–7877. 17. A superior unitary oxygen electrode with accelerated mass transfer and highly exposed active sites for rechargeable air-based batteries, Journal of Power Sources, 2021, 488, 229468. 18. Cobalt Incorporated Porous Aromatic Framework for CO2/CH4 Separation. Industrial & Engineering Chemistry Research, 2018, 57, 10985-10991. (Inside Cover) 19. Highly Efficient Oxygen Reduction Reaction Electrocatalysts Synthesized under Nanospace Confinement of Metal–Organic Framework.ACS Nano, 2017, 11(8), 8379-86. 20. Ultrastable α phase nickel hydroxide as energy storage materials for alkaline secondary batteries. Applied Surface Science, 2018,435, 635. 21. Inhibition of zinc dendrites in zinc-based flow batteries, Frontiers in Chemistry, 2020, 8, 55. 22. PAF-1 as oxygen tank to in-situ synthesize edge-exposed O-MoS2 for highly efficient hydrogen evolution. Catalysis Today, 2020, 347, 56-62. Patents: 1. Structure of a gradient hydrophilic/hydrophobic air electrode and its preparation method, ZL201910045021.8 2. Structure of air electrode for zinc air flow battery and preparation method thereof,ZL201710179128.2 3. A non-metal self-supporting air electrode and a preparation method thereof, ZL201810559307.3 4. Preparation method of carbon based hybrid capacitor material Co-doped with nitrogen, phosphorus and fluorine, ZL201710136476.1 5. A nitrogen and phosphorus co-doped carbon-based non-metallic oxygen reduction/precipitation dual-effect catalyst and its preparation method, ZL201710521211.3 6. A host-guest strategy for the synthesis of nitrogen and other heteroatom double-doped carbon-based double-effect catalysts, ZL201910497970.X 7. Preparation method of an electrochemically assisted nitrogen and phosphorus double doped carbon base air electrode, ZL201910289810.6 8. A Zinc-ion single flow battery, ZL201210260404.5 9. Zinc-nickel single flow battery positive electrode and its preparation and Zinc-nickel single flow battery, ZL201210260050.4 10. An alkaline Zinc-vanadium flow battery, ZL 201310306674.X 11. A Zinc-iron single flow battery, ZL 201210315782.9 12. An all-vanadium flow battery system, ZL 201320607243.2 13. A Zinc-nickel flow battery structure and Zinc-nickel flow battery system, ZL 201210560255.4 14. A Lead-acid-all-vanadium hybrid Energy storage battery, ZL 201310167808.4 15. A neutral zinc-iron dual flow battery, ZL 201310694610.1 16. A Zinc-nickel dual liquid flow battery, ZL 201310696105.0 17. A water Zinc-ion single flow battery, ZL 201310696151.0 AwardsPatentHonor RewardAdmissions Information |