Associate Professor, Northeast Normal University, China
Zihao Xing is an Associate Professor at the College of Chemistry, Northeast Normal University, China. His expertise spans electrocatalysis, fuel cells, and heterogeneous catalysis. He earned his Ph.D. in Physical Chemistry from Jilin University, where he developed innovative hydrogen energy conversion catalysts. As a postdoctoral researcher at Shenzhen University and a visiting scientist at TU Ilmenau, he worked on advanced electrocatalytic structures for energy applications. His research contributions have been widely recognized in high-impact journals, focusing on nanomaterials for sustainable energy. With numerous highly cited publications, he has significantly advanced oxygen reduction reaction (ORR) and battery electrocatalysis. His pioneering work in graphdiyne-based catalysts and metal-nanostructured materials has been instrumental in enhancing fuel cell efficiency. Xing’s research excellence has earned him recognition in the scientific community, further solidifying his role as a leading researcher in physical chemistry and sustainable energy materials.
PROFESSIONAL PROFILE
Google Scholar
Orcid
Scopus
STRENGTHS FOR THE AWARD
Zihao Xing demonstrates exceptional expertise in electrocatalysis, energy conversion materials, and fuel cells, with significant contributions to developing high-performance catalysts for sustainable energy applications. His extensive publication record, including works in Advanced Materials, Chemical Engineering Journal, and Nano Research, showcases his impact in the field, with high citation counts reflecting the recognition of his research by the scientific community. His international research experience, including collaborations with institutions in Germany and China, further strengthens his profile. Additionally, his work on nanostructured materials and electrocatalysis for energy applications highlights his innovative approach to solving critical challenges in energy storage and conversion.
AREAS FOR IMPROVEMENT
While Zihao Xing has an impressive research portfolio, expanding his leadership in large-scale funded projects and increasing collaborations with industry partners could further solidify his impact. Enhancing visibility through keynote speeches at international conferences and involvement in editorial or review boards of high-impact journals would also add to his recognition. Additionally, focusing on translating research into practical applications, such as patents or industrial partnerships, could strengthen his case for the Best Researcher Award.
EDUCATION
π Ph.D. in Physical Chemistry (2013-2019) – Jilin University, China
- Thesis: Rational Design and Activity Regulation of Hydrogen Energy Conversion Catalysts
- Supervisor: Prof. Wensheng Yang
- Exchange Student: State Key Laboratory of Organic Solids, ICCAS, Beijing
π M.Sc. in Physical Chemistry (2013-2019) – Jilin University, China
- Thesis: Structure Design of Nanostructured Graphdiyne Electrocatalysts
π B.Sc. in Applied Chemistry (2009-2013) – Jilin University, China
- Thesis: Synthesis of Precious Metal Nanoparticles and Carbon-Based Nanostructures
EXPERIENCE
π¨βπ« Associate Professor (2022-Present) – College of Chemistry, Northeast Normal University, China
- Leading research in hydrogen-electric energy conversion catalysts
π¬ Postdoctoral Researcher (2019-2021) – Shenzhen University, China
- Focused on designing highly active electrocatalysts for batteries
- Supervisor: Prof. Chenliang Su
π Visiting Scientist (2019-2021) – TU Ilmenau, Germany
- Specialized in applied nanophysics and electrocatalysis
- Supervisor: Prof. Yong Lei
AWARDS & HONORS
π Highly Cited Researcher Recognition β Multiple publications in high-impact journals
π Outstanding Young Scientist Award β Recognized for contributions to electrocatalysis
π Best Research Paper Award β Acknowledged for groundbreaking work in Zn-air batteries
π Postdoctoral Fellowship β Shenzhen University, China
π Academic Excellence Scholarship β Jilin University
π Visiting Scientist Grant β TU Ilmenau, Germany
RESEARCH FOCUS
π¬ Electrocatalysis & Energy Materials β Development of high-performance catalysts for fuel cells and batteries
β‘ Oxygen Reduction Reaction (ORR) & Hydrogen Evolution β Enhancing efficiency in sustainable energy conversion
π§ͺ Nanostructured Materials β Engineering carbon-based and metal nanostructures for advanced applications
π Graphdiyne-Based Catalysts β Designing novel materials for green energy solutions
π Fuel Cells & Metal-Air Batteries β Improving performance and durability of energy storage devices
PUBLICATION TOP NOTES
π Preferentially Engineering FeN4 Edge Sites onto Graphitic Nanosheets for Highly Active and Durable Oxygen Electrocatalysis in Rechargeable ZnβAir Batteries
π Sensitive Colorimetric Sensor for Point-of-Care Detection of Acetylcholinesterase Using Cobalt Oxyhydroxide Nanoflakes
π Self-Templating Construction of N, P-Co-Doped Carbon Nanosheets for Efficient Electrocatalytic Oxygen Reduction Reaction
π Stabilizing Single-Atomic Ruthenium by Ferrous Ion Doped NiFe-LDH Towards Highly Efficient and Sustained Water Oxidation
π Structure Engineering of PtCu3/C Catalyst from Disordered to Ordered Intermetallic Compound with Heat-Treatment for the Methanol Electrooxidation Reaction
π Optimizing the Activity of Pd-Based Catalysts Towards Room-Temperature Formic Acid Decomposition by Au Alloying
π Effect of Pt Cocatalyst on Visible Light Driven Hydrogen Evolution of Anthracene-Based Zirconium Metal-Organic Framework
π Colloidal Silica Assisted Fabrication of N, O, S-Tridoped Porous Carbon Nanosheets with Excellent Oxygen Reduction Performance
π Boosting the Methanol Oxidation Reaction Activity of PtβRu Clusters via Resonance Energy Transfer
π Bovine Serum Albumin Assisted Preparation of Ultra-Stable Gold Nanoflowers and Their Selective Raman Response to Charged Dyes
π Nanocomposite: Keggin-Type Co4-Polyoxometalate@Cobalt-Porphyrin Linked Graphdiyne for Hydrogen Evolution in Seawater
π Weak Interaction Between Cations and Anions in Electrolyte Enabling Fast DualβIon Storage for PotassiumβIon Hybrid Capacitors
π Hexavalent Iridium Boosts Oxygen Evolution Performance
π Disordered Carbon Structures Enhance Capacitive Storage
π Polyoxometalate as the Assembly Material to Self-Assembled Ni(OH)2 Nanosheets with Electrocatalytic Performance
π Ligand Engineering of Co-MOF-74 with Hexaaminotriphenylene for Enhanced Oxygen Reduction Reaction in Zinc-Air Batteries
π Rational Design of Amino-Functionalized Pillar-Layered Co6O6 Cluster MOF for Gas Purification in the MTO Process
π Pyridine-Nitrogen Conjugated Covalent Organic Frameworks for High-Efficiency Gas-Solid Photocatalytic Reduction of CO2 to CO
π Promoting Mechanism of the Ru-Integration Effect in RuCo Bimetallic Nanoparticles for Enhancing Water Splitting Performance
π Sulfur and Nitrogen Dual-Doped Graphdiyne as a Highly Efficient Metal-Free Electrocatalyst for the Zn-Air Battery
CONCLUSION
With a strong foundation in electrocatalysis, nanomaterials, and sustainable energy applications, Zihao Xing is highly suitable for the Best Researcher Award. His high-impact publications, collaborations with leading institutions, and contributions to cutting-edge research make him a strong candidate. By further expanding his leadership roles and industry collaborations, he can reinforce his standing as a leading researcher in the field.