Prof. Dr. Kaipeng Wu, Sichuan University, China
Prof. Dr. Kaipeng Wu, a native of Zhangye, Gansu Province, China, is an esteemed researcher specializing in energy storage materials. He earned his Ph.D. in Metallurgy and Environment from Central South University, focusing on scalable graphene production and Li-ion batteries. Dr. Wu’s work advances nanostructured materials for batteries, capacitors, and fuel cells. His pioneering research includes high-performance cathodes, graphene-based composites, and eco-friendly synthesis techniques. With numerous publications in top journals like Advanced Energy Materials and Carbon, Dr. Wu’s innovations impact sustainable energy technologies. He is passionate about scaling novel energy solutions for global sustainability. šā”š
Publication Profile
Scopus
Educational Background šš¬š
Prof. Dr. Kaipeng Wu holds a Ph.D. from the School of Metallurgy and Environment, Central South University, China (2010ā2016). His doctoral research focused on developing innovative materials for Li-ion batteries and designing scalable approaches for graphene production. Prior to this, he earned his Bachelor’s degree in Material Science and Engineering from Ji Lin University, China (2005ā2009), where he built a strong foundation in material science. His academic journey reflects a deep commitment to advancing energy storage technologies and sustainable materials, paving the way for impactful contributions to the field. ā”š±āØ
Research Experiences š§Ŗā”š
Prof. Dr. Kaipeng Wu has extensively explored graphene and its composites for energy conversion and storage since 2015. His work includes scalable graphene oxide purification and the synthesis of nitrogen-doped and porous graphene. He developed nanosized transition metal oxides for high-capacity LIB anodes and advanced LiMnPO4/C cathodes using innovative techniques. His studies improved LiFePO4 cathode performance through Mn and Co substitution and optimized its rate capability using graphene-coated precursors. These projects, supported by prestigious grants, highlight his dedication to advancing battery technologies and sustainable energy solutions. ššāØ
Research Interests š¬ā”š
Prof. Dr. Kaipeng Wuās research focuses on designing and applying nanostructured materials for cutting-edge energy storage systems, including lithium-ion batteries (LIBs) and capacitors. He explores alternative battery technologies such as sodium/magnesium batteries, metal-air batteries, and fuel cells. A key aspect of his work involves developing innovative methods for the large-scale synthesis of graphene and its derivatives, with precise control over their shapes and properties. His contributions aim to revolutionize energy storage solutions, promoting efficiency, sustainability, and scalability in advanced energy technologies. ššš
Publication Top Notes
- Synergistic Corrosion Engineering on Metallic Manganese Toward High-Performance Electrochemical Energy Storage (2024, 5 citations) šāļøš
- Optimizing the Electrochemical Performance of Olivine LiMnxFe1-xPO4 Cathode Materials (2024, 3 citations) ā”šš
- Thermodynamic Equilibrium Theory-Guided Design and Synthesis of Mg-Doped LiFe0.4Mn0.6PO4/C Cathode (2024, 5 citations) ššš§Ŗ
- Ultra-Thin Hydrogen-Organic-Framework (HOF) Nanosheets for Ultra-Stable Alkali Ions Battery Storage (2024, 9 citations) šš¬šŖ
- Regeneration Behavior of FePO4Ā·2H2O from Spent LiFePO4 Under Extremely Acidic Conditions (2024, 7 citations) šš±ā”
- Rationalizing Na-Ion Solvation Structure for High-Voltage Sodium Metal Batteries (2023, 14 citations) š§šŖāļø
- Quenching-Induced Construction of Graphene-Wrapped Fe3O4 Composite (2023, 3 citations) šš¤š
- Interface Engineering of Space-Confined Fe3O4/FeS Heterostructures (2023, 2 citations) šš§²š
- Recent Progress in Advanced Organosulfur Cathode Materials for Rechargeable Lithium Batteries (2023, 13 citations) āļøš¬šæ
- V-Substituted Pyrochlore-Type Polyantimonic Acid for Lithium-Ion Storage (2023, 1 citation) š”ššµ