Professor Long Chen 👨🔬 is a distinguished researcher at Shihezi University, College of Chemistry and Chemical Engineering. He earned his Ph.D. (2016) and M.S. (2014) from the University of Chinese Academy of Sciences, following a B.S. in Applied Chemistry from Shenyang University of Chemical Technology (2011). His expertise lies in advanced nanomaterials for electrochemical applications ⚡, including energy storage and catalysis. With multiple NSFC-funded projects, high-impact publications 🏆, and patents, he has significantly contributed to materials science. Recognized with prestigious awards 🏅, he also mentors young scientists, fostering innovation in sustainable energy solutions 🌱.
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🔍 Summary of Suitability:
Prof. Long Chen, a distinguished researcher at Shihezi University, has made significant contributions to materials chemistry, electrochemistry, and nanotechnology. His extensive research in energy storage, electrocatalysis, and water splitting has led to groundbreaking advancements in metal-organic frameworks, zinc-ion batteries, and nanomaterial-based sensors. With a strong publication record, leadership in national research projects, and recognition through patents and awards, he is a prime candidate for the Best Researcher Award.
Education 🎓
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2014-2016: Ph.D. in Materials Physics and Chemistry, University of Chinese Academy of Sciences 🏛️
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2011-2014: M.S. in Materials Physics and Chemistry, University of Chinese Academy of Sciences 🧪
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2007-2011: B.S. in Applied Chemistry, Shenyang University of Chemical Technology ⚗️
Work Experience 💼
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2023-Present: Professor, Shihezi University, College of Chemistry and Chemical Engineering 👨🏫
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2019-2023: Associate Professor, Shihezi University 🏫
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2016-2019: Lecturer, Shihezi University 📖
Postdoctoral Experience 🧑🔬
Professional Development 🚀📖
Professor Long Chen 👨🏫 has made remarkable strides in materials science, focusing on electrochemical energy storage and catalysis ⚡. As a professor at Shihezi University, he has led multiple NSFC-funded projects, contributing to high-entropy materials and nanostructured catalysts 🏆. His prolific research output includes high-impact journal publications 📚, patents 🏅, and international conference presentations 🎤. With postdoctoral experience at Lanzhou University, he has expanded his expertise in advanced functional materials 🔬. Committed to mentoring young researchers 👨🎓, he continues to drive innovation in sustainable energy solutions 🌱, pushing the boundaries of electrochemical applications for a greener future.
Research Focus 🔍🤖
Professor Long Chen’s research focuses on electrochemical energy storage and conversion ⚡, nanomaterials 🔬, and catalysis ⚗️. His work explores high-entropy materials, metal-organic frameworks (MOFs), and defect-engineered nanostructures for applications in zinc-ion batteries, hydrogen evolution reactions (HER), and heavy metal ion detection 🔍. He specializes in designing advanced electrocatalysts for sustainable energy 🌱 and optimizing electrochemical interfaces to enhance efficiency. Through innovative materials synthesis 🏗️ and structural engineering, he develops next-generation battery electrodes 🔋 and catalytic systems for clean energy solutions, contributing to the progress of renewable energy technologies 🌍.
Awards & Honors 🏆
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Second Prize in Natural Science, Xinjiang Production and Construction Corps 🏅 – 2024
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Gold Award, China International College Students’ Innovation Competition 🥇 – 2024 (as the first mentor)
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Outstanding Innovation and Entrepreneurship Mentor, Ministry of Education 🎓 – 2024
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Keynote Speaker, International Conference on Sustainable Energy Development 🎤 – 2023
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Best Presentation Award, Micro-Nano Materials and Interface Characterization Forum 🏆 – 2024
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Multiple National Patents Holder 🏅 – Including advanced electrocatalysts & battery materials
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Principal Investigator for NSFC Research Projects 🔬 – Secured major national funding for energy materials research
Publications & Citations 📚
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MOF-derived Zn/Co co-doped MnO/C microspheres for aqueous zinc-ion battery – Chemical Engineering Journal, 2023, Cited by: 125 🔬📖
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MOF-derived Se doped MnS/Ti3C2Tx for rocking-chair zinc-ion battery – Nano Research, 2024, Cited by: 89 ⚡🔋
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Highly stable Zn anodes with 3D zincophilic buffer layer – Nano Research Energy, 2024, Cited by: 76 🔋⚙️
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NiCo2O4 nanoparticles on graphene for heavy metal detection – Chemical Engineering Journal, 2022, Cited by: 132 🏭⚡
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Cu8S5 decorated porous carbon for water splitting – Chemical Engineering Journal, 2022, Cited by: 110 💦⚡
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NiCo2S4 microspheres on graphene for water splitting – Nano Research, 2022, Cited by: 98 ⚛️💧
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Ultrafine MFe2O4 nanocrystals for Cu(ii) detection – Journal of Materials Chemistry A, 2021, Cited by: 145 🏗️🧪
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Ni3S2/Co9S8 hybrid nanostructures for water splitting – Journal of Colloid and Interface Science, 2023, Cited by: 87 ⚛️🌊
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Zincophilic Ti3C2Cl2 MXene for dendrite-free Zn anode – Journal of Materials Science & Technology, 2024, Cited by: 92 🔋🧪
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High-capacity Ti3C2Tx MXene supercapacitors – ACS Applied Materials & Interfaces, 2023, Cited by: 105 ⚡📊