Associate Professor, Donghua University, China
Dr. Yuanyuan Ma is a distinguished Associate Professor and Master’s Supervisor at the College of Materials Science and Engineering, Donghua University, and is affiliated with the State Key Laboratory of Advanced Fiber Materials. A rising star in the field of materials science, Dr. Ma has made significant contributions to energy storage, electrocatalysis, and sustainable materials development. Since earning her Ph.D. in 2019, she has demonstrated exceptional leadership in research and innovation, with over 50 SCI-indexed publications, including 29 as first or corresponding author. 📈 Her work has earned her an h-index of 30, a testament to the global impact and recognition of her research.
🔹Professional Profile
ORCID
Google Scholar
🏆Strengths for the Award
-
High Research Productivity:
Dr. Ma has published 50 SCI papers, with 29 as first or corresponding author in top-tier journals such as Angewandte Chemie International Edition, Advanced Energy Materials, Chemical Society Reviews, and Nano-Micro Letters. This demonstrates her consistent, high-level contribution to cutting-edge research.
-
Research Impact and Recognition:
An h-index of 30 at her career stage is an impressive metric, reflecting a strong citation record and influence in the field of materials science and energy research.
-
Leadership in Research Projects:
She has successfully led national and regional research projects, including funding from the National Natural Science Foundation of China and the Natural Science Foundation of Shanghai, indicating her ability to secure competitive grants and lead research teams.
-
Strong Academic Credentials and Progression:
Earning a Ph.D. from Fudan University, followed by a rapid promotion from Lecturer to Associate Professor at Donghua University, underlines her strong academic background and recognition by her institution.
-
Focused and Relevant Research Area:
Her research in electrocatalysis, energy storage, and hydrogen production is not only scientifically important but also aligned with global energy and sustainability goals, increasing its practical and societal relevance.
🎓 Education
Dr. Ma earned her Ph.D. in Chemistry from Fudan University in 2019, where she conducted cutting-edge research under the supervision of the esteemed. During her doctoral studies, she developed a strong foundation in electrochemical energy storage, organic-inorganic hybrid materials, and molecular-level material design. Her academic training equipped her with both deep theoretical knowledge and strong experimental skills in advanced materials science.
👩🔬 Experience
Immediately after completing her Ph.D., Dr. Ma joined Donghua University as a Lecturer in July 2019. In recognition of her remarkable academic output and research leadership, she was promoted to Associate Professor within a short span—an exceptional achievement in academia. At Donghua, she serves as a Master’s Supervisor, guiding graduate students in breakthrough material innovation. She also plays a key role in managing and executing several national and provincial research projects, including grants from the National Natural Science Foundation of China and the Natural Science Foundation of Shanghai. 🏅
Dr. Ma’s research is centered on the design and development of advanced materials for sustainable energy solutions. Her work spans several critical areas of materials science. One key focus is the tailoring of inorganic nanomaterials to achieve high-performance electrocatalysis and energy storage, where she strategically engineers nanostructures to enhance catalytic activity and improve energy efficiency. Another major area involves the molecular-level design of organic electrode materials specifically for aqueous battery applications, aiming to develop safer, more environmentally friendly alternatives to conventional batteries. In addition, Dr. Ma is at the forefront of efforts to innovate water electrolysis systems for clean and efficient hydrogen production, contributing to the advancement of hydrogen as a viable alternative energy source.
📚 Publications Top Notes
Electrocatalytic Reduction of Nitrate – A Step Towards a Sustainable Nitrogen Cycle
Authors: H. Xu, Y. Ma, J. Chen, W. Zhang, J. Yang
Summary:
This highly cited review outlines recent advances in nitrate electroreduction technologies. It discusses catalyst materials, mechanisms, and system designs that enable conversion of nitrate into valuable products like ammonia. The work is a key resource for researchers tackling water pollution and aiming for a sustainable nitrogen cycle.
An Environmentally Friendly and Flexible Aqueous Zinc Battery Using an Organic Cathode
Authors: Z. Guo, Y. Ma, X. Dong, J. Huang, Y. Wang, Y. Xia
Summary:
This pioneering paper presents a safe, flexible zinc-ion battery with an organic cathode, offering a green alternative to conventional batteries. The battery system demonstrates strong performance, stability, and environmental compatibility—ideal for wearable electronics and sustainable storage.
Recent Progress of Rechargeable Batteries Using Mild Aqueous Electrolytes
Authors: J. Huang, Z. Guo, Y. Ma, D. Bin, Y. Wang, Y. Xia
Summary:
This review covers technological and chemical advancements in rechargeable batteries with aqueous electrolytes, focusing on improving safety, cost, and performance. It serves as a guide for future battery development with an emphasis on green and scalable energy systems.
High-Energy Rechargeable Metallic Lithium Battery at −70°C Enabled by a Cosolvent Electrolyte
Authors: X. Dong, Y. Lin, P. Li, Y. Ma, J. Huang, D. Bin, Y. Wang, Y. Qi, Y. Xia
Summary:
This study introduces a lithium-metal battery that operates at extreme cold (−70°C) using a cosolvent electrolyte. The battery maintains high energy density and reliability under frigid conditions, making it a breakthrough for aerospace and military applications.
Residual Chlorine Induced Cationic Active Species on a Porous Copper Electrocatalyst for Highly Stable Electrochemical CO₂ Reduction to C₂⁺
Authors: M. Li, Y. Ma, J. Chen, R. Lawrence, W. Luo, M. Sacchi, W. Jiang, J. Yang
Summary:
This paper develops a chlorine-modified porous copper catalyst that boosts the CO₂ reduction reaction to form C₂⁺ hydrocarbons like ethylene. It offers insights into catalyst design and stability, aiding progress toward carbon capture and utilization technologies.
🏁 Conclusion
Dr. Yuanyuan Ma exemplifies excellence in research, mentorship, and scientific innovation. Her impactful work in the design of sustainable materials and clean energy systems has received wide acclaim, positioning her as a leader in materials science. With a proven track record of high-impact publications, successful research grants, and student supervision, Dr. Ma is not only advancing science but also shaping the next generation of researchers. Her commitment to solving global energy challenges makes her an ideal candidate for any prestigious research or academic award. 🏆🌍