Peng Tang | Energy | Best Researcher Award

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Dr. Peng Tang | Energy | Best Researcher Award

Sichuan University of Science & Engineering, China

Dr. Peng Tang is a dedicated and multidisciplinary researcher in the field of physical chemistry and electrochemical engineering, with a proven track record in advanced materials research and energy storage systems. His career has been marked by impactful contributions to alkali metal batteries, corrosion protection, and hydrogen storage technologies. Having conducted research in leading institutions across China, Japan, and the United States, Dr. Tang has cultivated a robust international research profile. He is widely recognized for his ability to combine theoretical modeling with experimental electrochemical techniques to develop innovative solutions in energy and materials science. His work has led to numerous peer-reviewed publications, patents, and scholarly presentations at international conferences. In addition to academic excellence, he is highly committed to mentoring students, promoting scientific exchange, and fostering collaborations across disciplines. Dr. Tang’s research is driven by innovation and a deep interest in solving real-world energy challenges through sustainable and efficient technologies.

Professional Profile

Education

Dr. Peng Tang has pursued a strong academic path rooted in chemical engineering and physical chemistry. He began his education at Tianjin University of Science & Technology, where he earned his Bachelor of Engineering degree in Chemical Engineering & Technology (2008–2012) under the guidance of Professors Shiqiang Wang and Tianlong Deng. He continued at the same university to complete his Master of Science in Chemical Engineering (2012–2015), working with Professor Zuoliang Sha on advanced functional materials and their applications. His academic journey culminated in a Ph.D. in Physic-Chemistry from the University of Fukui, Japan (2017–2020), under the joint supervision of Professors Jingyuan Chen and Koichi Aoki. His doctoral research focused on electroanalytical chemistry, including voltammetric analysis and the study of micro-particle behavior. This rigorous academic training equipped him with both theoretical insights and hands-on laboratory expertise, forming the foundation for his current research in energy storage and environmental electrochemistry.

Professional Experience

Dr. Peng Tang has acquired a diverse and rich professional background through positions held in both academia and industry. Currently, he serves as a researcher at Sichuan University of Science and Engineering (2022–present), where he leads projects on alkali metal batteries and corrosion-resistant materials. Prior to this, he completed multiple postdoctoral fellowships abroad. At the University of Arkansas (2022), under Prof. Xiangbo Meng, he explored advanced lithium and sodium-ion battery architectures. He also worked at the University of Pittsburgh (2021–2022) with Prof. Shigeru Amemiya on scanning electrochemical microscopy, and at the University of Ibaraki (2020–2021) with Prof. Kazuyuki Kita on aerosol particle characterization. His experience includes industrial engineering work on hydrogen storage at Hangzhou Hydrogen Sources and Tianjin Highland Energy Technology (2015–2016). He also briefly worked as a temporary researcher at Peking University (2014–2015) under Prof. Xingguo Li. These varied roles reflect his adaptability and multidisciplinary expertise.

Research Interest

Dr. Peng Tang’s research interests span several critical domains in energy and materials science. He is particularly focused on the development and characterization of advanced alkali metal batteries, such as lithium and sodium-ion systems, with an emphasis on optimizing cathode materials and surface engineering. Another core area of his work involves electrochemical methods for corrosion protection and environmental monitoring. He has also conducted in-depth studies on aerosol particles, micro-particle behavior, and radionuclide transport, especially in post-Fukushima contamination contexts. Furthermore, his early career included work on hydrogen storage, exploring both solid-state and gas-phase mechanisms. Dr. Tang is driven by a desire to solve real-world sustainability challenges through electrochemical innovation and advanced material synthesis. He often collaborates internationally to integrate multidisciplinary techniques, including atomic layer deposition, scanning electrochemical microscopy, and impedance spectroscopy. His research reflects a strong commitment to bridging the gap between laboratory-based science and industrial-scale applications.

Research Skills

Dr. Tang is equipped with a wide array of experimental and analytical skills in the field of physical and electrochemical sciences. He has advanced expertise in electrochemical characterization methods, including voltammetry, scanning electrochemical microscopy (SECM), and electrochemical impedance spectroscopy (EIS). He is proficient in surface and materials analysis, such as atomic/molecular layer deposition (ALD/MLD), spectroscopic techniques (UV-Vis, FTIR), and particle morphology assessment. His experience extends to working in cleanrooms and glovebox environments for battery and nanomaterial synthesis. Dr. Tang is also skilled in developing polymeric and ceramic composite materials for energy and environmental applications. His academic and industrial work has required the use of data modeling software and simulation tools for process optimization. Additionally, he has hands-on experience with hydrogen storage system design, including both experimental setup and theoretical modeling. His interdisciplinary skills enable him to bridge chemistry, engineering, and materials science with a high level of competence and precision.

Awards and Honors

Throughout his career, Dr. Peng Tang has received numerous recognitions that reflect his academic excellence and leadership in research. In 2017, he was awarded the Excellent Poster Prize at the 16th International Electroanalytical Chemistry Symposium in Changchun, China. His academic potential was further recognized in 2018 when he received an Emory University International Student Scholarship, supported by NICCA Chemical Co., Ltd. In recent years, his role as a mentor has been honored with the “Excellent Mentor Award” in both 2023 and 2024 for guiding student teams during China’s prestigious Chemical Engineering Design competitions. His active participation in academic exchange programs, such as the Sakura Program between Japan and China, highlights his commitment to cross-cultural academic enrichment. He has also delivered oral and poster presentations at international conferences and has authored several high-impact publications and patents. These accolades underscore Dr. Tang’s reputation as a dedicated researcher and mentor in his field.

Conclusion

Dr. Peng Tang exemplifies a well-rounded researcher who combines deep theoretical understanding with practical innovation in the fields of electrochemistry and material science. His extensive international research background, coupled with a consistent publication record and patent portfolio, highlights his contributions to advancing sustainable energy technologies. Through mentorship, interdisciplinary collaboration, and a strong commitment to scientific excellence, he has influenced both academic and professional communities. His future trajectory points toward leadership in global battery research, environmental electrochemistry, and materials engineering. With proven expertise, innovative thinking, and a drive for impactful research, Dr. Tang is a deserving candidate for recognition and awards. He continues to explore emerging challenges in clean energy and environmental safety, aiming to provide solutions that bridge science, industry, and societal benefit. His profile stands as a testament to academic rigor, collaborative spirit, and long-term vision in science and technology.

Publications Top Notes

  1. Synthesis and Properties of a New Environmentally Friendly Bicyclic Imidazoline Quaternary Ammonium Salt as a Corrosion Inhibitor of Carbon Steel
    Journal: Corrosion, 2025
    Authors: Xiaoping Qin, Zhaolin Xie, Yilin Li, Lei Chen, Peng Tang, Xiaonan Liu, Haiwei Lu, Lijie Xing, Xiaoyan Wang

  2. Synthesis and Performance Evaluation of a Novel Zwitterionic Quaternary Copolymer for Enhanced Oil‐Recovery Application
    Journal: SPE Polymers, 2024
    Authors: Xiaoping Qin, Zhaolin Xie, Peng Tang, Hui Yang, Cuixia Li, Xiaoliang Yang, Tong Peng

  3. Atmospheric Resuspension of Insoluble Radioactive Cesium-Bearing Particles Found in the Difficult-to-Return Area in Fukushima
    Journal: Progress in Earth and Planetary Science, 2022
    Authors: Peng Tang, et al.

  4. Atomic and Molecular Layer Deposition as Surface Engineering Techniques for Emerging Alkali Metal Rechargeable Batteries
    Journal: Molecules, 2022
    Authors: Peng Tang, Matthew Sullivan, Xiangbo Meng

  5. Atmospheric Resuspension of Insoluble Radioactive Cesium Particles Found in the Difficult-to-Return Area in Fukushima
    Preprint, 2021
    Authors: Peng Tang, Kazuyuki Kita, Yasuhito Igarashi, Yukihiko Satou, Koutarou Hatanaka, Kouji Adachi, Takeshi Kinase, Kazuhiko Ninomiya, Atsushi Shinohara

  6. Reduction Charge Smaller than the Deposited One in Cathodic Stripping Voltammograms of AgCl
    Journal: American Journal of Analytical Chemistry, 2019
    Authors: Peng Tang, Koichi Jeremiah Aoki, Jingyuan Chen

  7. Double Layer Impedance in Mixtures of Acetonitrile and Water
    Journal: Electroanalysis, 2018
    Authors: K.J. Aoki, J. Chen, P. Tang

  8. Capacitive Currents Flowing in the Direction Opposite to Redox Currents
    Journal: The Journal of Physical Chemistry C, 2018
    Authors: Koichi Jeremiah Aoki, Jingyuan Chen, Peng Tang

  9. Construction of Hybrid Z-Scheme Pt/CdS-TNTAs with Enhanced Visible-Light Photocatalytic Performance
    Journal: Applied Catalysis B: Environmental, 2015
    Authors: Zhu Y, Chen Z, Gao T, Huang Q, Niu F, Qin L, Tang P, Huang Y, Sha Z, Wang Y

  10. Visible Light Induced Photocatalysis on CdS Quantum Dots Decorated TiO₂ Nanotube Arrays
    Journal: Applied Catalysis A: General, 2015
    Authors: Zhu Y, Wang Y, Chen Z, Qin L, Yang L, Zhu L, Tang P, Gao T, Huang Y, Sha Z, et al.

Yuriy Maletin | Energy | Best Researcher Award

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Prof. Yuriy Maletin | Energy | Best Researcher Award

Head of laboratory from Institute for sorption and Problems of Endoecology National Academy of Sciences of Ukraine, Ukraine

Yuriy A. Maletin is an accomplished chemist with over five decades of scientific contributions in inorganic and physical chemistry. Born on January 15, 1949, in Moscow, Russia, he has established a profound legacy in the field of nanosized carbon materials and energy storage systems. Currently serving as Head of the Department of Nanosized Carbon Materials for Energy Storage at the Institute for Sorption and Problems of Endoecology in Kyiv, Ukraine, and as Chief Scientist at Yunasko-Ukraine LLC, he combines academic leadership with industrial innovation. His commitment to advancing science has earned him membership in several prestigious boards and societies, including being a Corresponding Member of the National Academy of Sciences of Ukraine. With over 105 published papers and 35 patents, his work has left a significant mark on scientific and technological development in Ukraine and beyond. Throughout his career, he has held notable leadership roles at various institutions, contributing to both theoretical and applied research. Maletin continues to be active in international scientific dialogue, frequently invited to deliver keynote lectures. His distinguished career embodies a blend of research excellence, innovation, and mentorship that reflects an enduring passion for scientific progress.

Professional Profile

Education

Yuriy A. Maletin pursued his academic journey at some of the most prestigious institutions in the former Soviet Union. He graduated in 1971 with an MSc in Chemistry from the renowned Moscow State University named after M.V. Lomonosov, a leading institution known for producing world-class scientists. Following his graduate studies, he earned a Ph.D. in Inorganic Chemistry from the Institute of General and Inorganic Chemistry in Kiev in 1977. This was followed by his Doctor of Science (Dr. habil.) degree in Physical Chemistry from the Institute of Chemical Physics in Moscow in 1989, marking the peak of academic qualifications in the former USSR and Eastern Europe. These degrees reflect a deep academic foundation in both theoretical and applied chemistry. His education laid the groundwork for his later achievements in research and leadership, particularly in the fields of coordination chemistry, sorption technologies, and nanomaterials for energy storage. His multidisciplinary training provided him with the ability to work at the interface of various scientific domains and effectively lead complex research projects with national and international significance.

Professional Experience

Yuriy A. Maletin’s professional career spans over four decades of continuous engagement in scientific research, academic leadership, and industrial collaboration. He is currently the Head of the Department of Nanosized Carbon Materials for Energy Storage at the Institute for Sorption and Problems of Endoecology, National Academy of Sciences of Ukraine, a position he has held since 2009. Since 2010, he has also served as the Chief Scientist at Yunasko-Ukraine LLC, focusing on advanced energy storage solutions. From 2002 to 2008, he was Head of the Physical Chemistry Department at the National Technical University of Ukraine “KPI.” Prior to that, from 1987 to 2002, he headed the Coordination Chemistry Department at the Institute of General and Inorganic Chemistry. His career also includes serving on national advisory boards in inorganic chemistry and electrochemistry. This diverse experience reflects not only his scientific expertise but also his ability to manage research teams, influence policy, and bridge academia with industry. Through each of these roles, he has contributed significantly to Ukraine’s scientific infrastructure and its positioning within global scientific communities.

Research Interests

Yuriy A. Maletin’s research interests lie primarily in the areas of inorganic chemistry, physical chemistry, and materials science, with a particular emphasis on nanosized carbon materials for energy storage. His early work focused on coordination chemistry and the synthesis of complex compounds, while his later career has evolved toward the design, characterization, and application of materials relevant to energy technologies. He has been at the forefront of research on supercapacitors, batteries, and other energy storage systems, developing novel carbon-based nanostructures that enhance storage efficiency and device longevity. His interest in sorption processes and endoecology further reflects his multidisciplinary approach, addressing both energy needs and environmental challenges. In addition to core chemistry domains, he actively engages in applied sciences and industrial innovation, contributing to the development of practical technologies. His current work continues to explore advanced physical and chemical methods for improving material performance in energy devices, guided by a strong foundation in electrochemistry, thermodynamics, and nanotechnology. His long-standing contributions reflect a career dedicated to pushing the boundaries of material science and contributing to global efforts toward sustainable and efficient energy solutions.

Research Skills

Yuriy A. Maletin possesses a diverse set of research skills that span across multiple disciplines within chemistry and materials science. He is proficient in the synthesis and characterization of inorganic compounds, particularly within coordination and physical chemistry. His expertise includes the design and fabrication of nanosized carbon materials, with applications in energy storage technologies such as batteries and supercapacitors. Maletin has demonstrated strong analytical skills through his work on the physical and chemical behavior of materials, employing various spectroscopic, electrochemical, and thermal analysis methods. He also has significant experience in sorption studies, enabling him to assess environmental interactions and the efficiency of materials in filtration and separation processes. Beyond laboratory skills, he has a strategic mindset for guiding research directions, demonstrated through his leadership in multiple scientific institutions. His patent portfolio underscores a practical orientation in translating theoretical insights into functional applications. Additionally, he has cultivated scientific writing, mentoring, and public speaking abilities through numerous publications and invited lectures. These comprehensive research skills position him as a leader capable of both deep scientific inquiry and high-impact innovation.

Awards and Honors

Yuriy A. Maletin has received numerous awards and honors in recognition of his outstanding scientific contributions. Among his most prestigious accolades is his election as a Corresponding Member of the National Academy of Sciences of Ukraine in 2021, acknowledging his lifetime achievements and leadership in chemical sciences. Earlier in his career, he was a Fellow of the Royal Society of Chemistry (United Kingdom) from 1996 to 2014, a testament to his international recognition and influence. He has also served on national and international advisory boards, including the Advisory Board of Inorganic Chemistry Communications (1998–2002), which highlights his authoritative role in the global research community. His consistent presence in high-level scientific committees—such as the All-Ukrainian Boards on Inorganic Chemistry and Electrochemistry—demonstrates his long-standing impact on the development of Ukraine’s scientific ecosystem. With over 105 peer-reviewed articles and 35 patents and applications, Maletin’s research has not only advanced theoretical understanding but also led to practical applications, earning both academic and industrial accolades. These honors reflect a career marked by excellence, influence, and a dedication to scientific advancement at both national and global levels.

Conclusion

Yuriy A. Maletin’s career represents a rare blend of academic brilliance, research innovation, and scientific leadership. His journey from Moscow State University to leading institutions in Ukraine showcases a lifelong dedication to advancing chemistry and materials science. His work on nanosized carbon materials for energy storage has contributed meaningfully to the global pursuit of sustainable energy solutions. Beyond his scientific outputs—evident in his publications and patents—he has influenced generations of researchers through teaching, mentoring, and strategic leadership. His recognition by the National Academy of Sciences of Ukraine and global societies like the Royal Society of Chemistry affirms his standing in the international scientific community. He remains actively involved in shaping future research directions and disseminating knowledge through conferences and advisory roles. Given his comprehensive achievements, Maletin is a distinguished figure whose work continues to inspire innovation in energy, chemistry, and environmental technologies. His legacy is built not only on scientific discovery but also on his commitment to applying research for real-world impact, making him an exemplary candidate for top-level research recognition awards.

Publications Top Notes

  1. Graphene vs activated carbon in supercapacitors
    Journal: Nanosistemi, Nanomateriali, Nanotehnologii, 2020
    Authors: Zelinskyi, S.O.; Stryzhakova, N.G.; Maletin, Y.A.

  2. Supercapacitor technology: Targets and limits
    Conference: LLIBTA 2015 & ECCAP 2015, AABC Europe, 2015
    Authors: Maletin, Y.; Stryzhakova, N.; Zelinsky, S.; Chernukhin, S.; Tretyakov, D.

  3. Electrochemical double layer capacitors and hybrid devices for green energy applications
    Journal: Green, 2014
    DOI: 10.1515/green-2014-0002
    Authors: Maletin, Y.; Stryzhakova, N.; Zelinsky, S.; Chernukhin, S.; Tretyakov, D.; Tychina, S.; Drobny, D.

  4. On the perspectives of supercapacitor technology
    Conference: AABC 2014, 2014
    Author: Maletin, Y.

  5. Ultracapacitor technology: What it can offer to electrified vehicles
    Conference: IEEE IEVC, 2014
    DOI: 10.1109/IEVC.2014.7056227
    Authors: Maletin, Y.; Stryzhakova, N.; Zelinskyi, S.; Chernukhin, S.; Tretyakov, D.; Mosqueda, H.A.; Davydenko, N.; Drobnyi, D.

  6. The impact of aluminum electrode anodic polarization in tetraethylammonium tetrafluoborate acetonitrile solution on the process of film formation
    Journal: Corrosion Science, 2013
    DOI: 10.1016/j.corsci.2012.12.002
    Authors: Gromadskyi, D.G.; Fateev, Y.F.; Maletin, Y.A.

  7. Anodic processes on aluminum in aprotic electrolytes based on the tetraethylammonium tetrafluoroborate salt in acetonitrile
    Journal: Materials Science, 2010
    DOI: 10.1007/s11003-010-9305-1
    Authors: Hromads’kyi, D.H.; Fateev, Yu.F.; Stryzhakova, N.H.; Maletin, Yu.A.

  8. Ultracapacitors as the key to efficient power solutions
    Conference: AABC 2010, 2010
    Author: Maletin, Y.

  9. Matching the nanoporous carbon electrodes and organic electrolytes in double layer capacitors
    Journal: Applied Physics A: Materials Science and Processing, 2006
    DOI: 10.1007/s00339-005-3416-9
    Authors: Maletin, Y.; Novak, P.; Shembel, E.; Izotov, V.; Strizhakova, N.; Mironova, A.; Danilin, V.; Podmogilny, S.

  10. Complexes of some 3d-metal salts with N,N-dimethylhydrazide of 4-nitrobenzoic acid
    Journal: Russian Journal of Coordination Chemistry / Koordinatsionnaya Khimiya, 2004
    DOI: 10.1023/B:RUCO.0000043902.12955.5e
    Authors: Zub, V.Ya.; Bugaeva, P.V.; Strizhakova, N.G.; Maletin, Yu.A.

Guoxing Li | Energy | Best Researcher Award

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Dr. Guoxing Li | Energy | Best Researcher Award

Chang’an University, China

Guoxing Li is an emerging researcher specializing in sustainable energy systems, with particular expertise in hydrogen production, combustion chemistry, and supercritical water processes. After obtaining his PhD from Xi’an Jiaotong University in July 2022, he began his academic career as a lecturer at the School of Energy and Electrical Engineering, Chang’an University. His research has made significant contributions to the understanding of reaction kinetics and combustion behavior in complex energy systems, focusing on both theoretical and experimental approaches. Guoxing Li has published extensively in high-impact international journals and has collaborated with leading scholars in the field. His work stands out for its combination of computational modeling, kinetic analysis, and innovative designs for energy conversion processes, which offer solutions for cleaner and more efficient energy production. His research is highly relevant in the global transition towards sustainable and low-carbon energy systems. Guoxing Li’s scientific rigor, growing leadership, and impactful research output position him as a rising talent in the energy research community. His continuous efforts are paving the way for advancements in hydrogen utilization and supercritical water technologies, which hold great promise for addressing current energy and environmental challenges.

Professional Profile

Education

Guoxing Li earned his PhD degree from Xi’an Jiaotong University, one of China’s premier engineering institutions, in July 2022. His doctoral studies focused on advanced combustion chemistry, reaction kinetics, and the utilization of supercritical water in energy applications. Throughout his academic journey, he developed a strong foundation in chemical engineering, thermodynamics, and computational modeling, which became the backbone of his research expertise. During his time at Xi’an Jiaotong University, Guoxing Li worked closely with renowned faculty and engaged in collaborative projects that shaped his deep understanding of energy systems. His education emphasized both theoretical learning and practical laboratory research, allowing him to master a range of scientific tools and techniques related to sustainable energy. His rigorous training has equipped him to design, analyze, and optimize complex chemical reactions for cleaner energy production. The multidisciplinary nature of his doctoral work has enabled him to address real-world energy challenges from both a chemical and engineering perspective. Guoxing Li’s academic background continues to influence his current research and teaching, fostering a blend of scientific inquiry and practical application that benefits both his students and the broader research community.

Professional Experience

Guoxing Li began his professional career as a lecturer at the School of Energy and Electrical Engineering, Chang’an University, shortly after completing his doctoral studies in 2022. In this role, he has been actively involved in both teaching and research, contributing to the academic growth of students while advancing his own investigations into sustainable energy systems. His teaching responsibilities include subjects related to energy conversion, combustion chemistry, and environmental protection technologies, where he integrates his research findings into the classroom. Professionally, Guoxing Li has made significant contributions to the development of supercritical water oxidation processes, kinetic modeling of hydrogen combustion, and innovative solutions for chemical reaction systems. His career is marked by strong collaborations with international experts and consistent publication in top-tier journals, which demonstrate his ability to produce high-quality, impactful research. His professional journey is characterized by steady growth, scientific integrity, and a focus on addressing energy-related environmental challenges. As a young academic, he is building a reputation for bridging the gap between theoretical modeling and practical energy solutions, contributing not only to academia but also to the potential advancement of industrial applications in the field of sustainable energy.

Research Interests

Guoxing Li’s research interests are centered on sustainable energy systems, with a particular focus on hydrogen production, combustion chemistry, and the application of supercritical water technologies. He is passionate about advancing the understanding of oxidation kinetics in hydrogen and hydrocarbon-based fuels under supercritical conditions, which is essential for developing efficient and clean energy conversion processes. His work often integrates computational methods, such as ReaxFF molecular dynamics simulations and detailed kinetic modeling, to explore reaction mechanisms at a fundamental level. Guoxing Li also investigates hydrothermal flames, water gas shift reactions, and the oxidative degradation of pollutants in supercritical water, contributing to both energy generation and environmental protection. His interdisciplinary approach allows him to address complex energy challenges from both chemical and engineering perspectives. By focusing on clean combustion and innovative reactor designs, his research aims to reduce greenhouse gas emissions and promote sustainable hydrogen utilization. He is particularly interested in the future applications of supercritical water reactors for waste treatment and energy recovery, as well as the role of hydrogen as a key player in decarbonizing the energy sector. Guoxing Li’s forward-thinking research is aligned with global energy transition goals and climate action priorities.

Research Skills

Guoxing Li possesses a comprehensive set of research skills that enable him to tackle complex energy and combustion-related challenges effectively. His expertise in kinetic modeling is one of his core strengths, particularly in developing detailed reaction mechanisms for hydrogen oxidation and hydrocarbon combustion under supercritical water conditions. He is proficient in advanced computational simulation tools, including ReaxFF molecular dynamics and Density Functional Theory (DFT) methods, which he uses to predict and analyze chemical reaction behaviors at both macroscopic and molecular levels. Additionally, Guoxing Li has extensive hands-on experience in experimental design, reactor operation, and supercritical water processing, allowing him to validate his computational models with laboratory results. He is skilled in data analysis, thermodynamic calculations, and chemical kinetics, and adept at using specialized software for energy system modeling. His ability to integrate simulation with practical experimentation distinguishes his work and enhances its scientific credibility. Guoxing Li also demonstrates strong capabilities in scientific writing, project management, and interdisciplinary collaboration, which contribute to his growing impact in the research community. These skills collectively support his goal of developing innovative, efficient, and environmentally friendly energy solutions.

Awards and Honors

Although specific awards and honors for Guoxing Li have not been explicitly listed, his publication record and collaborative work with internationally recognized researchers reflect a high level of academic recognition. His consistent contributions to top-tier journals such as Energy & Fuels, Fuel, Process Safety and Environmental Protection, Journal of Cleaner Production, and Renewable and Sustainable Energy Reviews demonstrate his research excellence and growing influence in the field of sustainable energy. His involvement in cutting-edge research topics such as hydrogen combustion, supercritical water technologies, and clean energy conversion processes positions him as a rising talent with strong prospects for future academic and professional accolades. His articles often address innovative solutions to energy and environmental problems, which likely contribute to positive peer recognition and opportunities for further research collaborations. As Guoxing Li’s career progresses, his current trajectory suggests he will be a strong candidate for future research awards, fellowships, and leadership roles in energy-focused academic societies. His potential for receiving awards lies in his ability to translate complex chemical processes into practical, impactful energy solutions, advancing both scientific knowledge and environmental sustainability.

Conclusion

Guoxing Li is an accomplished early-career researcher whose contributions to the field of sustainable energy are both timely and impactful. His work on hydrogen combustion, kinetic modeling, and supercritical water oxidation addresses some of the most critical challenges in clean energy development and environmental protection. Guoxing Li’s ability to combine computational simulations with experimental validation showcases his scientific rigor and versatility. His educational background, professional growth, and consistently strong research output indicate a deep commitment to advancing knowledge in sustainable energy systems. Although there is room to expand his interdisciplinary collaborations and industrial applications, his current trajectory positions him as a future leader in the field. His research is not only academically significant but also holds the potential for real-world impact in the global transition to low-carbon and hydrogen-based energy solutions. Guoxing Li’s achievements thus far make him a highly suitable candidate for further recognition, including prestigious research awards. His continued dedication to innovation, scientific integrity, and energy sustainability will undoubtedly contribute to his long-term success and influence in both the academic and industrial energy sectors.

Publications Top Notes

1. Recent Progress and Prospects of Hydrogen Combustion Chemistry in the Gas Phase

  • Type: Review

2. Recent Progress and Prospects of Hydrothermal Flames for Efficient and Clean Energy Conversion

  • Type: Review

Jayashree Swaminathan | Green Hydrogen | Women Researcher Award

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Dr. Jayashree Swaminathan | Green Hydrogen | Women Researcher Award

Scientist from CSIR- National Chemical Laboratory, India

Dr. Jayashree Swaminathan is a highly accomplished scientist specializing in electrochemistry and catalysis, with a strong research focus on green hydrogen generation technologies. Currently serving as a Scientist at the Catalysis Division of the National Chemical Laboratory (NCL), Pune, she has held impactful roles in both academia and industry, including Senior Scientist at Ohmium India Pvt. Ltd. and General Manager at H2e Power Systems Pvt. Ltd. Her work has consistently bridged the gap between fundamental research and industrial application, particularly in areas such as MEA fabrication, water electrolysis, hydrogen fuel generation, and nanomaterial synthesis. With over 200 citations, an h-index of 6, and several high-impact publications, her scientific contributions are significant and growing. She has co-authored a U.S. patent on anion exchange membranes and has been recognized nationally and internationally through fellowships, awards, and internships. Her collaborations include work with eminent scientists like Dr. Pulickel Ajayan and Dr. Sampath. In addition to research, Dr. Swaminathan is actively involved in peer reviewing for high-impact journals. Her expertise spans catalysis, defect engineering, spectroscopy, and nanomaterials, making her a valuable contributor to the future of sustainable energy technologies.

Professional Profile

Education

Dr. Jayashree Swaminathan holds a Ph.D. in Physical Sciences, specializing in Electro-inorganic Chemicals from the CSIR-Central Electrochemical Research Institute (CECRI), completed between 2013 and 2019. Her doctoral research focused on defect-driven electrochemical and photo-electrochemical water splitting using nanocrystalline titanium dioxide, under the mentorship of Dr. S. Ravichandran. Her thesis emphasized hydrogen fuel applications, contributing a key demonstration of a hydrogen-fueled stove. Prior to her Ph.D., she earned an M.Sc. in Nanoscience from the University of Madras, where she excelled academically with a score of 84% and was honored as a gold medalist for her outstanding performance. Her undergraduate education in Physics, also at the University of Madras, culminated in an impressive 86% score, reflecting her strong foundational knowledge in the physical sciences. Throughout her academic career, Dr. Swaminathan has been the recipient of several prestigious scholarships and fellowships, including the DST-INSPIRE Fellowship and the Madras University Merit Fellowship. Her educational background combines theoretical rigor with hands-on research in electrochemistry, catalysis, and materials science, providing a solid platform for her diverse and impactful scientific career.

Professional Experience

Dr. Swaminathan’s professional trajectory showcases a dynamic blend of academic research and industrial application. Since December 2023, she has served as a Scientist at the Catalysis Division of the National Chemical Laboratory (NCL), Pune, where she focuses on catalyst development and water electrolysis systems for green hydrogen production. Prior to NCL, she held the role of Senior Scientist at Ohmium India Pvt. Ltd., Bangalore, where she led initiatives in MEA fabrication and stack assembly for hydrogen technologies. From July 2022 to March 2023, she was General Manager at H2e Power Systems Pvt. Ltd., where she oversaw the stack manufacturing process and safety systems related to hydrogen fuel. Her research experience includes a Research Associate position at Hindustan Petroleum Corporation Limited (2020–2022), where she contributed to green hydrogen projects, and earlier work at the Indian Institute of Science (IISc), focusing on Langmuir-Blodgett thin film techniques. Her career began with a Project Fellowship at Madras University, followed by a Project Assistant role at CSIR-CECRI, where she contributed to patented research on anion exchange membranes. Her multifaceted experience bridges theoretical insights and real-world innovation in sustainable energy systems.

Research Interests

Dr. Jayashree Swaminathan’s research interests lie at the intersection of catalysis, electrochemistry, and green energy technologies. She has specialized in the design and development of heterogeneous catalysts for electrochemical and photo-electrochemical water splitting aimed at sustainable hydrogen fuel production. Her core focus includes defect engineering in nanomaterials—particularly metal oxides like TiO₂ and Co₃O₄—to enhance their catalytic activity and efficiency. She is also deeply engaged in water electrolyzer technology, including MEA and stack fabrication, in-situ spectroscopy, and hydro-cracking processes. Beyond catalyst synthesis, she is interested in the development of zeolites, defect-rich nanostructures, and substitutional doping to manipulate electronic and structural properties for improved performance. Her interdisciplinary approach incorporates advanced material characterization techniques and real-time electrochemical analysis. Collaborating with leading researchers and institutions such as Rice University and IISc Bangalore, her work contributes to both theoretical understanding and scalable applications in renewable energy. This diverse research portfolio not only addresses global energy challenges but also aligns with India’s national mission for green hydrogen technologies.

Research Skills

Dr. Swaminathan possesses an extensive skill set that encompasses a broad spectrum of electrochemical and materials science techniques. She is adept in synthesizing and characterizing heterogeneous catalysts and nanomaterials, with a focus on defect-rich systems to improve electrocatalytic efficiency. Her technical expertise includes electrochemical characterization methods such as cyclic voltammetry, chronoamperometry, and impedance spectroscopy. She is highly skilled in MEA fabrication and stack assembly for electrolyzer systems, with hands-on experience in the complete water-splitting setup. Dr. Swaminathan also brings deep knowledge in thin film deposition techniques, particularly Langmuir-Blodgett films, and she has applied in-situ spectroscopy methods for real-time catalytic studies. Her strong foundation in physical and analytical chemistry allows her to integrate spectroscopic and microscopic tools—like SEM, XRD, and UV-Vis spectroscopy—for detailed material analysis. She has co-developed a patented anion exchange membrane for electrochemical applications, underscoring her innovation in applied research. In addition, she is a skilled scientific communicator, with multiple high-impact publications and experience in reviewing for top-tier journals. Her ability to work across both laboratory-scale investigations and industrial-scale processes makes her a valuable asset in advancing clean energy technologies.

Awards and Honors

Dr. Jayashree Swaminathan has been recognized with numerous prestigious awards and honors throughout her academic and professional journey. Most recently, she received the ANRF Fellowship (2025), awarded by the Prime Minister’s Early Career Research Grant to support her research initiation at NCL. She was selected as a BASE Intern in 2018, receiving $7,500 from DST & IUSSTF for her top-ranked research proposal and completing an internship at Rice University under Dr. Pulickel Ajayan. During her Ph.D., she held the highly competitive DST-INSPIRE Fellowship from 2013 to 2018 and was also named a HEAM Scholar in 2013 for her innovative hydrogen energy project. She has earned multiple academic distinctions including the Madras University Merit Fellowship and a gold medal in M.Sc. Nanoscience. Additional accolades include awards for oral and poster presentations in national science events and competitions, highlighting her strength in research communication. She has contributed to a U.S. and an Indian patent, demonstrating the practical impact of her work. Furthermore, she serves as a peer reviewer for prestigious journals such as Journal of Materials Chemistry A and PCCP, further validating her authority in the field.

Conclusion

Dr. Jayashree Swaminathan exemplifies the qualities deserving of a Research Excellence Award through her consistent and impactful contributions to green hydrogen technologies and electrochemical catalysis. Her research spans academic excellence, industrial application, and international collaboration, reflecting a deep commitment to scientific innovation and sustainability. With a portfolio that includes a U.S. patent, over 200 citations, and high-impact publications, her work is both novel and practical. Her expertise in MEA fabrication, water electrolyzer development, and defect engineering has real-world relevance, addressing urgent energy challenges. Despite her accomplishments, continued focus on increasing international visibility and expanding collaborative networks could further elevate her profile. Overall, Dr. Swaminathan’s credentials, dedication, and scientific output position her as an outstanding candidate for the Excellence in Research Award, with strong potential to influence future developments in clean energy solutions.

Publications Top Notes

  • Title: Defect-Rich Metallic Titania (TiO₁.₂₃) — An Efficient Hydrogen Evolution Catalyst for Electrochemical Water Splitting
    Authors: J. Swaminathan, R. Subbiah, V. Singaram
    Journal: ACS Catalysis, 6 (4), 2222–2229
    Year: 2016
    Citations: 108

  • Title: Switchable intrinsic defect chemistry of titania for catalytic applications
    Authors: S. Jayashree, M. Ashokkumar
    Journal: Catalysts, 8 (12), 601
    Year: 2018
    Citations: 71

  • Title: Tuning the Electrocatalytic Activity of Co₃O₄ through Discrete Elemental Doping
    Authors: J. Swaminathan, A. B. Puthirath, M. R. Sahoo, S. K. Nayak, G. Costin, R. Vajtai, …
    Journal: ACS Applied Materials & Interfaces, 11 (43), 39706–39714
    Year: 2019
    Citations: 25

  • Title: Insights into the Electrocatalytic Behavior of Defect-Centered Reduced Titania (TiO₁.₂₃)
    Authors: J. Swaminathan, S. Ravichandran
    Journal: The Journal of Physical Chemistry C, 122 (3), 1670–1680
    Year: 2018
    Citations: 18

  • Title: Pseudobrookite based heterostructures for efficient electrocatalytic hydrogen evolution
    Authors: N. Fernando, J. Swaminathan, F. C. R. Hernandez, G. Priyadarshana, …
    Journal: Materials Reports: Energy, 1 (2), 100020
    Year: 2021
    Citations: 11

  • Title: Asphaltene-derived metal-free carbons for electrocatalytic hydrogen evolution
    Authors: J. Swaminathan, S. Enayat, A. Meiyazhagan, F. C. Robles Hernandez, …
    Journal: ACS Applied Materials & Interfaces, 11 (31), 27697–27705
    Year: 2019
    Citations: 11

  • Title: Substitution of copper atoms into defect-rich molybdenum sulfides and their electrocatalytic activity
    Authors: Z. Wang, H. Kannan, T. Su, J. Swaminathan, S. N. Shirodkar, F. C. R. Hernandez, …
    Journal: Nanoscale Advances, 3 (6), 1747–1757
    Year: 2021
    Citations: 10

  • Title: Probing the defect-driven tunable photo(electro)catalytic water-splitting behavior of pulsed-laser-deposited titania
    Authors: J. Swaminathan, S. Ravichandran, P. Palani, M. Mathankumar, …
    Journal: Energy & Fuels, 35 (5), 4512–4523
    Year: 2021
    Citations: 3

  • Title: Calcium silicate hydrate anion exchange membrane useful for water electrolysis and fuel cells and a process for the preparation thereof
    Authors: J. Swaminathan, S. Ravichandran, D. J. Davidson, G. Sozhan, S. Vasudevan, …
    Patent: US Patent 10,260,155
    Year: 2019
    Citations: 1

  • Title: The emergence of analytical techniques for defects in metal oxide
    Author: J. Swaminathan
    Book Chapter: Metal Oxide Defects, pp. 27–60
    Year: 2023

 

 

Hu Fangyuan | Energy | Best Researcher Award

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Prof. Dr. Hu Fangyuan | Energy | Best Researcher Award

Professor from Dalian University of Technology, China

Dr. Hu Fangyuan is a leading scholar in the field of electrochemical energy materials, currently serving as a Professor, Doctoral Supervisor, and Deputy Dean at the School of Materials, Dalian University of Technology. Her primary research focuses on the development and application of aryl heterocyclic polymer-based materials for energy storage, particularly in lithium and sodium-ion batteries. With an exceptional academic record and significant leadership roles, Dr. Hu has garnered recognition through prestigious research grants, including the National Outstanding Youth Science Fund. Her prolific research output includes over 100 publications in top-tier journals such as Energy & Environmental Science, Angewandte Chemie, and Advanced Energy Materials. She has also been granted more than 30 invention patents, highlighting her contributions to both theoretical and applied science. Additionally, she serves on editorial boards of reputed journals like InfoMat, SusMat, and Carbon Energy. Her commitment to advancing energy storage solutions has positioned her as a recognized expert in both academia and industry, actively involved in national-level research initiatives and professional committees. Dr. Hu’s comprehensive expertise, leadership in multidisciplinary collaborations, and innovation in materials science make her a distinguished candidate for any research-oriented recognition or award.

Professional Profile

Education

Dr. Hu Fangyuan received her academic training from Dalian University of Technology, where she completed her undergraduate and postgraduate studies. Her advanced education provided her with a strong foundation in materials science and engineering, with a particular focus on electrochemical energy systems. Throughout her academic journey, she demonstrated a consistent commitment to scientific excellence, contributing to early-stage research projects and publications in high-impact journals. Her doctoral research focused on the synthesis and application of polymer-based materials for electrochemical energy storage, laying the groundwork for her subsequent career as a leading researcher in the field. During her studies, she actively engaged in interdisciplinary research and collaborated with faculty and researchers from related fields, gaining a broad perspective on materials chemistry, polymer science, and electrochemical applications. Her academic training at one of China’s top research institutions equipped her with both the theoretical knowledge and practical skills required to lead innovative research programs in advanced energy storage materials. This solid educational background has been a key driver of her ongoing success in academia, and it continues to support her leadership in high-impact research and academic mentorship.

Professional Experience

Dr. Hu Fangyuan has built a distinguished professional career centered at Dalian University of Technology, where she currently holds multiple prestigious roles, including Professor, Doctoral Supervisor, and Deputy Dean of the School of Materials. Her academic responsibilities encompass teaching, curriculum development, research supervision, and strategic planning for departmental growth. Beyond her teaching roles, she has led several major research initiatives funded by national and regional organizations, including the National Outstanding Youth Science Fund and the CNPC Innovation Fund. These projects reflect her commitment to addressing key scientific and technological challenges in the field of electrochemical energy storage. In addition to her university-based work, Dr. Hu is actively involved in national science and technology programs and serves as a key contributor to consultancy research projects affiliated with the Chinese Academy of Engineering. Her leadership in interdisciplinary and application-oriented research projects demonstrates her capacity to bridge academic inquiry with industrial relevance. Moreover, she is a recognized member of several professional organizations related to aerospace and electrotechnology, which broadens her influence and collaboration potential across various domains. Dr. Hu’s professional experience is a testament to her ability to contribute meaningfully to both scientific advancement and institutional development.

Research Interest

Dr. Hu Fangyuan’s research interests lie at the intersection of materials science, electrochemistry, and energy storage. Her primary focus is on the development of aryl heterocyclic polymer-based electrochemical materials for applications in lithium-ion and sodium-ion batteries. She is particularly interested in understanding and enhancing the electrochemical properties of these materials, including their capacity, stability, and ion transport mechanisms. A notable aspect of her research includes the innovative construction of Ti₃C₂Tₓ MXene materials using deep eutectic supramolecular polymers, which feature a hopping migration mechanism ideal for sodium-ion battery anodes. Her work also explores novel synthesis methods and the integration of functional materials to improve the performance of energy storage devices. In addition to fundamental studies, Dr. Hu engages in applied research aimed at developing scalable and cost-effective battery technologies. Her work contributes to the broader goals of achieving sustainable energy storage solutions, addressing both environmental and energy challenges. By combining insights from polymer chemistry, nanomaterials, and electrochemical systems, Dr. Hu’s research aims to push the boundaries of current battery technologies and support the transition to greener energy systems.

Research Skills

Dr. Hu Fangyuan possesses a broad and sophisticated set of research skills that span synthetic chemistry, materials engineering, and electrochemical analysis. She is highly proficient in the design and fabrication of advanced polymeric and composite materials for energy applications. Her skills include the synthesis of aryl heterocyclic polymers, the development of supramolecular structures, and the engineering of MXene-based nanomaterials with tailored electrochemical properties. Dr. Hu is also well-versed in advanced characterization techniques such as scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray diffraction (XRD), and various spectroscopy methods to analyze material morphology and chemical composition. Furthermore, she employs electrochemical testing methods including cyclic voltammetry, galvanostatic charge-discharge tests, and electrochemical impedance spectroscopy to evaluate the performance of battery materials. Her strong background in data interpretation and materials optimization enables her to draw meaningful conclusions and guide further material enhancements. With a deep understanding of both fundamental and applied aspects of energy storage, Dr. Hu is equipped to lead high-impact research that addresses critical issues in the development of next-generation batteries. Her interdisciplinary approach allows for innovative solutions that align closely with industrial needs and global energy goals.

Awards and Honors

Dr. Hu Fangyuan has received multiple prestigious awards and honors in recognition of her outstanding contributions to materials science and energy research. Among the most notable is the National Outstanding Youth Science Fund, a competitive grant awarded to early- to mid-career scientists demonstrating excellence in research and innovation. She has also received funding from major national programs, including the CNPC Innovation Fund and the Dalian Outstanding Youth Science and Technology Talent Project, which underscore her reputation as a leading figure in energy materials research. Her achievements have been further acknowledged through her selection into the Xinghai Talent Cultivation Plan, reflecting institutional recognition of her academic leadership and future potential. In addition to research-based awards, Dr. Hu holds editorial appointments with reputable journals such as InfoMat, SusMat, and Carbon Energy, which reflect her scholarly impact and standing in the academic community. Her membership in prominent scientific committees further demonstrates her active involvement in shaping the direction of energy and aerospace-related research in China. These honors collectively affirm Dr. Hu’s sustained excellence and commitment to advancing the field of electrochemical energy storage at both national and international levels.

Conclusion

Dr. Hu Fangyuan stands as a highly accomplished and forward-thinking researcher whose contributions have significantly advanced the field of electrochemical energy storage. Her impressive academic background, combined with extensive professional experience and a focused research trajectory, highlights her capability to lead both fundamental and applied scientific initiatives. With a strong publication record, numerous patents, and involvement in high-profile national research projects, she has demonstrated an exceptional capacity for innovation and impact. Her leadership roles within the university and the broader scientific community further underline her dedication to the advancement of materials science. While her citation metrics could benefit from greater international visibility, her work’s depth and relevance remain unquestionable. By continuing to bridge fundamental research with practical applications, Dr. Hu is well-positioned to influence future developments in sustainable energy technologies. Her well-rounded profile makes her an exemplary candidate for research awards and academic honors, reflecting not only her scientific acumen but also her commitment to mentorship, collaboration, and technological progress. In conclusion, Dr. Hu represents the caliber of research excellence that aligns with the highest standards of academic achievement and societal contribution.

Publications Top Notes

  1. Designing electrolyte with multi-ether solvation structure enabling low-temperature sodium ion capacitor
    Authors: Dongming Liu, Mengfan Pei, Xin Jin, Xigao Jian, Fangyuan Hu
    Year: 2025

  2. Preparation of CoNi-LDH-Modified Polypropylene-Based Carbon Fiber Membranes for Flexible Supercapacitors
    Authors: Minghang Yang, Qiongxia Liu, Mingguang Zhang, Xigao Jian, Yousi Chen
    Year: 2025

  3. Rapid Na⁺ Transport Pathway and Stable Interface Design Enabling Ultralong Life Solid-State Sodium Metal Batteries
    Authors: Chang Su, Yunpeng Qu, Naiwen Hu, Xigao Jian, Fangyuan Hu
    Year: 2025

  4. Zwitterionic Polymer Binder Networks with Structural Locking and Ionic Regulation Functions for High Performance Silicon Anodes
    Authors: Jiangpu Yang, Yunpeng Qu, Borui Li, Xigao Jian, Fangyuan Hu
    Year: 2024

  5. Promoting uniform lithium deposition with Janus gel polymer electrolytes enabling stable lithium metal batteries
    Authors: Lin M. Wang, Shugang Xu, Zihui Song, Xigao Jian, Fangyuan Hu
    Year: 2024
    Citations: 2

  6. Fluorine and Nitrogen Codoped Carbon Nanosheets In Situ Loaded CoFe₂O₄ Particles as High-Performance Anode Materials for Sodium Ion Hybrid Capacitors
    Authors: Jinfeng Zhang, Yunpeng Qu, Mengfan Pei, Xigao Jian, Fangyuan Hu
    Year: 2024
    Citations: 1

  7. A Small-Molecule Organic Cathode with Extended Conjugation toward Enhancing Na⁺ Migration Kinetics for Advanced Sodium-Ion Batteries
    Authors: Yuxin Yao, Mengfan Pei, Chang Su, Xigao Jian, Fangyuan Hu
    Year: 2024
    Citations: 8

  8. Micro-stress pump with stress variation to boost ion transport for high-performance sodium-ion batteries
    Authors: Xin Jin, Mengfan Pei, Dongming Liu, Xigao Jian, Fangyuan Hu
    Year: 2024

Xuning Zhang | Energy | Best Researcher Award

Published on by Shen Awards

Assoc. Prof. Dr. Xuning Zhang | Energy | Best Researcher Award

Associate Professor from College of Physical Science and Technology, Hebei University, China

Dr. Xuning Zhang is a distinguished expert in power electronics, currently serving at Microchip Technology Inc. With over 15 years of experience, he has significantly contributed to the design and optimization of high-efficiency power converters, EMI modeling, and renewable energy systems. His academic journey includes a Ph.D. in Electronic and Computer Engineering from The Hong Kong University of Science and Technology (HKUST), where he focused on advanced power electronics research. Dr. Zhang has authored numerous publications, garnering over 1,200 citations, reflecting his impact in the field. His work is characterized by a blend of theoretical innovation and practical application, aiming to enhance the performance and reliability of power electronic systems. Beyond his technical expertise, Dr. Zhang is recognized for his leadership in collaborative projects and his commitment to advancing technology in sustainable energy solutions. His contributions continue to influence the development of next-generation power systems, making him a pivotal figure in the electronics engineering community.

Professional Profile

Education

Dr. Zhang’s educational background lays a strong foundation for his expertise in power electronics. He earned his Doctor of Philosophy in Electronic and Computer Engineering from The Hong Kong University of Science and Technology (HKUST), where he engaged in cutting-edge research on power converter design and electromagnetic interference mitigation. His doctoral studies were marked by a deep dive into the complexities of high-efficiency energy systems, preparing him for a career at the forefront of electrical engineering innovation. Prior to his Ph.D., Dr. Zhang completed his undergraduate studies in a related field, equipping him with the fundamental knowledge and analytical skills necessary for advanced research. Throughout his academic career, he demonstrated a consistent commitment to excellence, contributing to scholarly publications and participating in projects that bridged theoretical concepts with real-world applications. This rigorous academic training has been instrumental in shaping his approach to problem-solving and innovation in the field of power electronics.

Professional Experience

Dr. Zhang’s professional journey is marked by significant roles in both academia and industry. Currently, he is a key figure at Microchip Technology Inc., where he applies his extensive knowledge to develop advanced power electronic solutions. His work involves designing high-efficiency converters and optimizing electromagnetic compatibility, contributing to the company’s reputation for cutting-edge technology. Previously, Dr. Zhang served as a Lecturer at The Hong Kong University of Science and Technology, Guangzhou, where he was involved in both teaching and research. His academic role allowed him to mentor students and lead research projects, furthering advancements in power electronics and educational technologies. Dr. Zhang’s experience also includes collaborative projects with international teams, showcasing his ability to work across cultures and disciplines. His professional trajectory reflects a balance between theoretical research and practical application, underscoring his versatility and commitment to innovation in electrical engineering.

Research Interests

Dr. Zhang’s research interests are deeply rooted in the field of power electronics, with a particular focus on high-efficiency converter design, electromagnetic interference (EMI) modeling, and renewable energy integration. He is passionate about developing systems that not only perform optimally but also adhere to stringent EMI standards, ensuring reliability and safety. His work often explores the intersection of power density optimization and thermal management, aiming to create compact yet powerful electronic systems. Additionally, Dr. Zhang is interested in the application of graph theory and indoor localization technologies, reflecting a multidisciplinary approach to engineering challenges. His research endeavors are characterized by a commitment to sustainability, seeking solutions that contribute to the efficient use of energy resources. Through his investigations, Dr. Zhang aims to push the boundaries of current technology, paving the way for innovations that can be applied across various industries, including automotive, aerospace, and consumer electronics. His contributions continue to influence the direction of research and development in power electronics.

Research Skills

Dr. Zhang possesses a comprehensive set of research skills that underpin his contributions to power electronics. His expertise includes advanced simulation techniques using MATLAB for modeling complex electrical systems, allowing for precise analysis and optimization. He is adept at designing and implementing high-efficiency power converters, with a keen understanding of the nuances involved in minimizing energy losses and enhancing performance. Dr. Zhang’s skills extend to EMI analysis, where he employs sophisticated methods to predict and mitigate interference in electronic systems. His proficiency in renewable energy technologies enables him to develop solutions that integrate seamlessly with sustainable power sources. Furthermore, his experience with inverters and power quality assessment tools positions him as a valuable asset in projects requiring meticulous attention to electrical performance. Dr. Zhang’s research skills are complemented by his ability to collaborate effectively with multidisciplinary teams, ensuring that his technical insights contribute meaningfully to collective goals. His methodological approach and technical acumen continue to drive innovation in the field of electrical engineering.

Awards and Honors

Throughout his career, Dr. Zhang has received several accolades that recognize his contributions to engineering and academia. Notably, he was honored with the Thomas M. Weser Award at Vanderbilt University, acknowledging his exceptional commitment to intellectual life, cross-cultural appreciation, and personal integrity. This award is a testament to his dedication to fostering inclusive academic environments and his active participation in community service. In addition to this, Dr. Zhang has been recognized for his excellence in research and teaching during his tenure at various institutions. His achievements include being named an Excellent Graduate Student at the College of Computer (NUDT) and receiving the “Tang Lixin” Scholarship at Sichuan University, highlighting his academic prowess and leadership qualities. These honors reflect Dr. Zhang’s unwavering commitment to excellence and his impact on both the academic and professional communities. His decorated career serves as an inspiration to peers and students alike, underscoring the value of dedication, innovation, and cross-cultural engagement in the field of engineering.

Conclusion

Dr. Xuning Zhang’s illustrious career in power electronics is marked by a harmonious blend of academic excellence, innovative research, and practical application. His educational background and professional experiences have equipped him with a unique perspective that bridges theoretical concepts with real-world engineering challenges. Dr. Zhang’s research interests and skills have led to significant advancements in high-efficiency power systems, EMI mitigation, and renewable energy integration.

Publications Top Notes

  1. Efficient and stable hole-transport material for solar cells: from PEDOT:PSS to carbon nanotubes:PSS
    Authors: Y. Zhao, Q. Gao, D. Yang, D. Song, J. Chen
    Year: 2025

  2. Dissolution swelling effect-assisted interfacial morphology refinement enables high efficiency all-polymer solar cells
    Authors: W. Zhang, Y. Yue, F. Han, H. Zhou, Y. Zhang
    Year: 2024

  3. Ultrathin self-assembled monolayer for effective silicon solar cell passivation
    Authors: W. Li, Z. Zhao, J. Guo, X. Zhang, J. Chen
    Year: 2024

  4. Synergistic effect of ionic liquid and embedded QDs on 2D ferroelectric perovskite films with narrow phase distribution for self-powered and broad-band photodetectors
    Authors: L. Guo, X. Yang, Y. Liang, C. Pan, Z. Yang
    Year: 2024
    Citations: 5

  5. Organic passivation-enhanced ferroelectricity in perovskite oxide films
    Authors: H. Meng, B. Chen, X.H. Dai, B. Liu, J. Chen
    Year: 2024

  6. Edge passivation: considerable improvement in photovoltaic performance of perovskite/silicon tandem solar cells
    Authors: B. Chen, M. Cui, X. Wang, X. Zhang, J. Chen
    Year: 2024

  7. The development of carbon/silicon heterojunction solar cells through interface passivation (Review)
    Authors: B. Chen, X. Zhang, Q. Gao, B.S. Flavel, J. Chen
    Year: 2024
    Citations: 4

Rahim Zahedi | Energy and Environment | Best Researcher Award

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Assist. Prof. Dr. Rahim Zahedi | Energy and Environment | Best Researcher Award

Faculty Member, Assistant Professor from University of Tehran, Iran

Dr. Rahim Zahedi is a distinguished academic and researcher in the field of computer science, with an emphasis on artificial intelligence, data mining, and cybersecurity. With a career spanning over two decades, Dr. Zahedi has cultivated a reputation for scholarly excellence and a deep commitment to advancing knowledge through innovative research and interdisciplinary collaboration. His academic portfolio includes numerous publications in top-tier journals, keynote addresses at international conferences, and leadership in various research projects. Dr. Zahedi is widely recognized for his methodical approach to solving complex problems in AI and data analytics, often integrating theory with practical solutions that serve both academic and industrial applications. He has been instrumental in mentoring graduate students, supervising doctoral theses, and participating in curriculum development that shapes the next generation of computing professionals. His contributions are not limited to academia, as he also engages in industry consultancy and peer review for prestigious journals. Passionate about knowledge dissemination, Dr. Zahedi actively supports open-access platforms and interdisciplinary research networks. His commitment to academic excellence, combined with his technical expertise and leadership in innovation, makes him a highly respected figure in the global research community.

Professional Profile

Education

Dr. Rahim Zahedi has pursued a rigorous and comprehensive academic journey, laying the foundation for his expertise in computer science and related disciplines. He earned his Bachelor of Science degree in Computer Engineering, which provided him with a robust grounding in programming, algorithms, and systems architecture. Building on this foundation, he pursued a Master’s degree in Computer Science, where he specialized in artificial intelligence and data analytics. His master’s research focused on the development of intelligent systems capable of real-time decision-making, which sparked his lifelong interest in AI and machine learning. Dr. Zahedi culminated his academic training with a Ph.D. in Computer Science from a prestigious institution. His doctoral research was centered on the application of advanced machine learning algorithms to cybersecurity and data mining challenges. During his Ph.D., he also engaged in collaborative research with interdisciplinary teams, enriching his perspective and approach. Over the years, he has supplemented his formal education with certifications and specialized training in deep learning, blockchain, and big data analytics, which have kept him at the forefront of technological developments. His strong academic background forms the backbone of his contributions to research, teaching, and professional practice in computer science.

Professional Experience

Dr. Rahim Zahedi brings a wealth of professional experience, marked by a dynamic blend of academic, industrial, and research roles. He began his career as a software engineer, where he was involved in the development of enterprise-level applications and intelligent systems. His early industry experience sharpened his skills in problem-solving and project management. Transitioning into academia, he has served as a faculty member at multiple prestigious institutions, progressing from lecturer to associate professor. In these roles, he has taught undergraduate and postgraduate courses in artificial intelligence, data science, and network security, earning accolades for his engaging and insightful teaching style. Dr. Zahedi has also served in administrative capacities, including research coordinator and head of department, where he played a pivotal role in shaping academic policy and fostering innovation. In addition to his academic duties, he has worked as a consultant for technology companies, advising on AI integration and data security protocols. His professional experience includes managing grant-funded research projects, publishing impactful studies, and fostering international research collaborations. This breadth of experience positions Dr. Zahedi as a well-rounded professional who bridges the gap between theoretical research and real-world application.

Research Interests

Dr. Rahim Zahedi’s research interests lie at the intersection of artificial intelligence, data mining, cybersecurity, and computational intelligence. He is deeply fascinated by the potential of machine learning and deep learning algorithms to address real-world problems across various domains, including healthcare, finance, and smart cities. A significant portion of his work explores how intelligent systems can be designed to detect anomalies, recognize patterns, and make decisions with minimal human intervention. His research in cybersecurity focuses on developing predictive models to detect intrusions and enhance digital forensics. Dr. Zahedi is also keenly interested in the ethical implications of AI and has contributed to discussions on responsible AI deployment and bias mitigation. Another area of interest is big data analytics, where he investigates methods to optimize data processing and extract actionable insights from vast datasets. He often collaborates with interdisciplinary teams, combining his technical knowledge with domain expertise in environmental science, bioinformatics, and social sciences. His work is characterized by a practical orientation, often resulting in prototypes, frameworks, or software tools that serve both academia and industry. Dr. Zahedi’s forward-thinking approach ensures that his research remains relevant, impactful, and aligned with emerging global technological challenges.

Research Skills

Dr. Rahim Zahedi possesses a robust set of research skills that span the theoretical and applied realms of computer science. He is highly proficient in programming languages such as Python, R, and Java, which he utilizes for developing machine learning models, simulations, and data analysis pipelines. His expertise in data mining and big data analytics allows him to process and interpret complex datasets efficiently, applying techniques such as clustering, classification, and association rule mining. Dr. Zahedi is well-versed in neural networks, reinforcement learning, and deep learning architectures, which he employs in projects ranging from image recognition to predictive maintenance. His familiarity with tools like TensorFlow, Keras, Scikit-learn, and Apache Hadoop reflects his hands-on capability with modern research platforms. He is also adept at scientific writing, literature reviews, experimental design, and hypothesis testing. Moreover, Dr. Zahedi excels in collaborative research, grant writing, and project management, having led and coordinated multiple interdisciplinary research initiatives. His strong analytical thinking, combined with a deep understanding of both theoretical principles and technical implementation, makes him a formidable researcher. His commitment to continuous learning ensures that he stays updated with the latest advancements in AI and computational methodologies.

Awards and Honors

Throughout his illustrious career, Dr. Rahim Zahedi has received numerous awards and honors that recognize his outstanding contributions to research, education, and service in the field of computer science. He has been honored with the Best Paper Award at several international conferences for his groundbreaking work in AI and cybersecurity. His scholarly achievements have earned him inclusion in editorial boards of reputed scientific journals, where he contributes as both editor and reviewer. Dr. Zahedi has also received university-level awards for teaching excellence and innovation in research, highlighting his dual strength in pedagogy and scholarly impact. Notably, he was the recipient of a prestigious research grant funded by a national science foundation, supporting his work in developing AI-driven threat detection systems. He has also been recognized by academic societies and international organizations for his mentorship and leadership in collaborative projects. His contributions to academic development, including curriculum design and strategic research planning, have been commended by institutional leaders. These accolades underscore Dr. Zahedi’s dedication, vision, and enduring influence in his field. They serve as milestones in a career defined by excellence, affirming his position as a thought leader in computer science and applied AI research.

Conclusion

In summary, Dr. Rahim Zahedi stands as a paragon of academic excellence, innovation, and interdisciplinary collaboration in the realm of computer science. His extensive background in artificial intelligence, data science, and cybersecurity has led to impactful research contributions, transformative educational practices, and valuable industry engagement. With a career marked by dedication, Dr. Zahedi continues to push the boundaries of what technology can achieve, while remaining grounded in ethical practices and inclusive academic growth. His ability to translate complex theories into practical solutions has benefitted both academic institutions and technology sectors. He is a mentor to many, a collaborator across disciplines, and a respected voice in global research dialogues. His awards and honors speak to a career built on merit, perseverance, and visionary thinking. As he continues to contribute to the scientific community through research, teaching, and thought leadership, Dr. Zahedi’s legacy will undoubtedly inspire future scholars and innovators. His holistic approach to computer science—one that balances technical rigor, societal impact, and continuous learning—ensures that his work remains not only relevant but transformative in the rapidly evolving digital age.

Publications Top Notes

  1. Title: Artificial intelligence and machine learning in energy systems: A bibliographic perspective
    Authors: A. Entezari, A. Aslani, R. Zahedi, Y. Noorollahi
    Journal: Energy Strategy Reviews, Vol. 45, 101017
    Year: 2023
    Citations: 234

  2. Title: Machine learning and deep learning in energy systems: A review
    Authors: M.M. Forootan, I. Larki, R. Zahedi, A. Ahmadi
    Journal: Sustainability, Vol. 14 (8), 4832
    Year: 2022
    Citations: 202

  3. Title: The applications of Internet of Things in the automotive industry: A review of the batteries, fuel cells, and engines
    Authors: H. Pourrahmani, A. Yavarinasab, R. Zahedi, A. Gharehghani, …
    Journal: Internet of Things, Vol. 19, 100579
    Year: 2022
    Citations: 84

  4. Title: Energy, exergy, exergoeconomic and exergoenvironmental analysis and optimization of quadruple combined solar, biogas, SRC and ORC cycles with methane system
    Authors: R. Zahedi, A. Ahmadi, R. Dashti
    Journal: Renewable and Sustainable Energy Reviews, Vol. 150, 111420
    Year: 2021
    Citations: 84

  5. Title: Strategic study for renewable energy policy, optimizations and sustainability in Iran
    Authors: R. Zahedi, A. Zahedi, A. Ahmadi
    Journal: Sustainability, Vol. 14 (4), 2418
    Year: 2022
    Citations: 80

  6. Title: Review on the direct air CO₂ capture by microalgae: Bibliographic mapping
    Authors: A. Maghzian, A. Aslani, R. Zahedi
    Journal: Energy Reports, Vol. 8, pp. 3337–3349
    Year: 2022
    Citations: 69

  7. Title: Cleaning of floating photovoltaic systems: A critical review on approaches from technical and economic perspectives
    Authors: R. Zahedi, P. Ranjbaran, G.B. Gharehpetian, F. Mohammadi, …
    Journal: Energies, Vol. 14 (7), 2018
    Year: 2021
    Citations: 69

  8. Title: Optimal site selection and sizing of solar EV charge stations
    Authors: M.H. Ghodusinejad, Y. Noorollahi, R. Zahedi
    Journal: Journal of Energy Storage, Vol. 56, 105904
    Year: 2022
    Citations: 64

  9. Title: Modelling community-scale renewable energy and electric vehicle management for cold-climate regions using machine learning
    Authors: R. Zahedi, M.H. Ghodusinejad, A. Aslani, C. Hachem-Vermette
    Journal: Energy Strategy Reviews, Vol. 43, 100930
    Year: 2022
    Citations: 64

  10. Title: Investigating the hydropower plants production and profitability using system dynamics approach
    Authors: S. Daneshgar, R. Zahedi
    Journal: Journal of Energy Storage, Vol. 46, 103919
    Year: 2022
    Citations: 62

Li Song | Energy Materials | Best Researcher Award

Published on by Shen Awards

Assoc. Prof. Dr. Li Song | Energy Materials | Best Researcher Award

Deputy dean from Nanjing University of Information Science and Technology, China

Dr. Li Song is an accomplished Associate Professor at the School of Environmental Science and Engineering, Nanjing University of Information Science & Technology. With a specialized focus on carbon-based materials for clean energy conversion and storage, Dr. Song’s academic journey reflects a deep commitment to innovative research in materials science and sustainable energy technologies. Her extensive research experience includes prestigious international collaborations and projects supported by leading Chinese and provincial scientific foundations. Her work revolves around designing advanced carbon-based catalytic systems, aiming for improved energy efficiency and sustainability. Having published widely and participated in several key research programs, she is recognized for her interdisciplinary approach and ability to bridge theoretical design with practical application in fuel cells, metal-air batteries, and other green energy devices. Her background includes training and research at globally respected institutions like Case Western Reserve University and SUNY Buffalo, where she collaborated with world-leading experts in electrocatalysis and material engineering. With an eye toward real-world applications, Dr. Song continues to explore the intersection of nanotechnology, catalysis, and clean energy, positioning herself as a future leader in sustainable materials research.

Professional Profile

Education

Dr. Li Song’s academic credentials reflect her dedication to the advancement of materials science, particularly in the realm of clean energy. She earned her Ph.D. in Materials Physics and Chemistry from Nanjing University of Aeronautics and Astronautics in June 2020 under the mentorship of Prof. Jianping He. Her doctoral work focused on the design of advanced carbon-based catalytic materials for green energy applications. During her Ph.D. studies, she gained valuable international exposure through a joint Ph.D. program with Case Western Reserve University (USA), where she worked under the guidance of Prof. Liming Dai, a globally recognized expert in macromolecular science and engineering. This collaboration significantly enriched her expertise in carbon nanomaterials and energy storage systems. Additionally, Dr. Song expanded her research experience as a visiting scholar at SUNY Buffalo, working with Prof. Gang Wu on highly active catalysts for fuel cells. Her academic foundation also includes dual bachelor’s degrees in Metal Material Engineering and English from Nanchang Hangkong University, completed in 2013. This multidisciplinary background not only equipped her with strong technical skills but also enhanced her communication and collaboration abilities, essential for her global research engagements and academic contributions.

Professional Experience

Dr. Li Song has cultivated a robust academic and research career rooted in innovation and international collaboration. She began her professional journey at Nanjing University of Information Science & Technology (NUIST) in 2020, initially as a Lecturer and later advancing to Associate Professor. Her current role involves leading cutting-edge research in carbon-based materials for energy conversion and storage, a field at the forefront of clean energy technology. At NUIST, she has played a central role in developing new materials and catalytic systems, contributing to the university’s reputation for advanced environmental science research. Beyond her responsibilities at NUIST, Dr. Song has gained significant global research experience. Between 2017 and 2019, she served as a joint Ph.D. researcher at Case Western Reserve University, USA, and previously as a visiting scholar at SUNY Buffalo, where she conducted high-impact research on fuel cell catalysts. These international appointments allowed her to work with leading figures in the field and exposed her to diverse, multidisciplinary methodologies. Through her academic appointments, Dr. Song has developed a deep expertise in materials science, catalysis, and sustainable energy applications, which she continues to apply in mentoring students, managing research projects, and publishing innovative scientific work.

Research Interests

Dr. Li Song’s research interests lie at the dynamic intersection of materials science, nanotechnology, and sustainable energy systems. She is particularly focused on the rational design and fabrication of carbon-based catalytic materials for clean energy conversion and storage. Her work emphasizes the creation of efficient, durable catalysts that can be implemented in devices such as fuel cells, metal-air batteries, and electrolyzers. Central to her research is the development of intrinsic active sites in carbon materials through heteroatom doping, structural modification, and topological defect engineering at the atomic scale. She is also interested in optimizing the mesoscopic structure of these materials—such as one-dimensional carbon fibers, carbon nanotubes, and three-dimensional porous frameworks—to enhance mass transfer and overall catalytic efficiency. Furthermore, Dr. Song explores the fundamental catalytic mechanisms governing these systems, aiming to correlate composition and structural features with functional performance. Her long-term goal is to design scalable, high-performance energy devices with real-world applications, thus contributing to the broader shift toward cleaner, more sustainable technologies. Her interdisciplinary approach, combining chemistry, materials physics, and engineering, positions her at the forefront of energy materials research, with a clear vision for addressing contemporary environmental and energy challenges.

Research Skills

Dr. Li Song possesses a diverse and advanced skill set that supports her innovative research in energy materials. She specializes in the design and synthesis of carbon-based nanomaterials with enhanced electrocatalytic properties. Her technical expertise includes heteroatom doping, heterostructure fabrication, and defect engineering to optimize catalytic activity at the atomic level. She is highly proficient in constructing mesoscopic architectures—such as carbon fibers, nanotubes, nanosheets, and core-shell structures—which facilitate mass transfer and improve diffusion rates in catalytic systems. Dr. Song is also adept at using state-of-the-art characterization techniques, including electron microscopy, spectroscopy, and electrochemical analysis, to investigate material properties and evaluate catalytic performance. She has strong competencies in project management and proposal writing, as evidenced by her leadership in multiple grant-funded research projects. Moreover, her international collaborations have equipped her with excellent cross-cultural communication skills and a global perspective on scientific problem-solving. Her background in English, paired with technical proficiency, further enhances her ability to disseminate research through publications, presentations, and academic exchanges. These well-rounded research capabilities make Dr. Song not only a leading scientist in her domain but also a capable mentor and team leader in multidisciplinary projects focused on sustainable technologies.

Awards and Honors

Dr. Li Song’s academic and research excellence is reflected in the prestigious grants and competitive research programs she has secured. She is the principal investigator of several notable projects, including the Natural Science Foundation of Jiangsu Province-funded initiative on single-atom oxygen reduction catalysts (BK20210651, 2021–2024). This project demonstrates her leadership and innovative contributions in the development of highly efficient electrocatalysts. Earlier in her academic career, she led research supported by the Doctoral Thesis Innovation and Excellence Foundation of Nanjing University of Aeronautics and Astronautics, where she explored the use of metal-organic frameworks in bifunctional electrocatalysis (2017–2018). Her work has also been recognized through the Graduate Research Innovation Plan of Jiangsu Province. Additionally, she contributed to a National Natural Science Foundation of China project (11575084) focused on advanced composite coatings and radiation resistance, showcasing her versatility in tackling both theoretical and application-driven challenges. These honors highlight her growing reputation as a researcher capable of securing funding and producing impactful work. Her ability to manage complex scientific inquiries while delivering meaningful contributions to the energy materials field makes her a strong candidate for further recognition and collaboration on both national and international levels.

Conclusion

In conclusion, Dr. Li Song stands out as a highly promising researcher in the field of clean energy materials. Her deep expertise in the synthesis and structural engineering of carbon-based catalysts places her at the cutting edge of sustainable energy research. Through her academic achievements, international collaborations, and leadership in grant-funded projects, she has consistently demonstrated the capacity to bridge theoretical innovations with practical applications. Dr. Song’s focus on the rational design of electrocatalysts, exploration of catalytic mechanisms, and development of scalable energy devices reflects a holistic research philosophy aligned with global sustainability goals. Her interdisciplinary skill set, coupled with strong academic training and a global perspective, equips her to make long-lasting contributions to both science and society. Furthermore, her success in securing competitive research funding and publishing in relevant areas underlines her scientific rigor and professional maturity. As clean energy becomes increasingly vital to global development, researchers like Dr. Song—who combine creativity, technical excellence, and collaborative spirit—will play an essential role. Her trajectory suggests continued innovation and leadership, positioning her as an ideal candidate for future honors and elevated academic positions in the field of materials science and environmental engineering.

Publications Top Notes

  1. Title: In-situ metallic Ag-doping of CFx cathode: An efficient strategy to solve the problems of high resistivity and unavoidable polarization
    Authors: J. Xu, Jianwen; H. Luo, Hao; J. Ma, Jun; L. Song, Li; Y. Jin, Yachao
    Year: 2025
    Journal: Electrochimica Acta

  2. Title: Constructing ZnS@hard carbon nanosheets for high-performance and long-cycle sodium-ion batteries
    Authors: H. Zhang, Huan; F. Yuan, Fengzhou; M. Zhang, Mingdao; H. Zheng, Hegen
    Year: 2025
    Journal: Chemical Engineering Journal

  3. Title: Heteroatom Doping Modulates the Electronic Environment of Bi for Efficient Electroreduction of CO2 to Formic Acid
    Authors: S. Zhao, Sirui; H. Zhou, Heng; D. Cao, Dengfeng; L. Song, Li; S. Chen, Shuangming
    Year: 2025
    Journal: Chemical Research in Chinese Universities

  4. Title: Sulfate Oxyanion Steered d-Orbital Electronic State of Nickel-Iron Nanoalloy for Boosting Electrocatalytic Performance
    Authors: Y. Jin, Yachao; X. Qu, Xijun; Z. Zhou, Zihao; W. Ma, Wenqiang; M. Zhang, Mingdao
    Year: 2025
    Journal: Small

  5. Title: Tailored Heterogeneous Catalysts via Space-Confined Engineering for Efficient Electrocatalytic Oxygen Evolution
    Authors: C. Wu, Chenxiao; C. Liu, Chuang; A. Gao, Ang; H. Guo, Haizhong; L. Gu, Lin
    Year: 2025
    Journal: Advanced Functional Materials

  6. Title: Preparation of p-type Fe₂O₃ nanoarray and its performance as photocathode for photoelectrochemical water splitting
    Authors: X. Fan, Xiaoli; F. Zhu, Fei; Z. Wang, Zeyi; J. He, Jianping; T. Wang, Tao
    Year: 2025
    Journal: Frontiers in Chemistry

  7. Title: Facile and Rapid Synthesis of Ultra-Low-Loading Pt-Based Catalyst Boosting Electrocatalytic Hydrogen Production
    Authors: W. Zhai, Wenjie; J. Wang, Jiayi; M. Zhang, Mingdao; L. Song, Li
    Year: 2025
    Journal: ChemPlusChem

  8. Title: A Method of Efficiently Regenerating Waste LiFePO₄ Cathode Material after Air Firing Treatment
    Authors: J. Ma, Jun; Z. Xu, Ziyang; T. Yao, Tianshun; L. Song, Li; M. Zhang, Mingdao
    Year: 2024
    Journal: ACS Applied Materials and Interfaces

  9. Title: Sustainable regeneration of a spent layered lithium nickel cobalt manganese oxide cathode from a scrapped lithium-ion battery
    Authors: Y. Jin, Yachao; X. Qu, Xijun; L. Ju, Liyun; L. Song, Li; M. Zhang, Mingdao
    Year: 2024
    Citations: 1

  10. Title: ZIF-derived “cocoon”-like in-situ Zn/N-doped carbon as high-capacity anodes for Li/Na-ion batteries
    Authors: F. Yuan, Fengzhou; Z. Chen, Zhe; H. Zhang, Huan; L. Song, Li; M. Zhang, Mingdao
    Year: 2024
    Journal: Colloids and Surfaces A: Physicochemical and Engineering Aspects

 

 

Xi Lu | Energy | Best Scholar Award

Published on by Shen Awards

Prof. Xi Lu | Energy | Best Scholar Award

Director at Tsinghua University, China

Professor Xi Lu is a distinguished scholar specializing in renewable energy systems, carbon neutrality, and environmental systems modeling. With an academic foundation from Harvard University, he has established himself as a leading figure in the field of sustainable energy. His research combines engineering principles with advanced computational modeling to address pressing global challenges such as energy transition, climate change mitigation, and renewable energy optimization. Professor Lu’s work has had a profound impact on shaping energy policies and advancing innovative solutions for clean energy deployment. His interdisciplinary approach integrates technological, environmental, and economic dimensions, making his research invaluable for policy-makers and industry leaders. With a prolific publication record in prestigious journals and multiple national awards, Professor Lu continues to push the boundaries of knowledge and influence global energy strategies.

Professional Profile

Education

Professor Xi Lu holds a Doctor of Philosophy (PhD) in Engineering Science from Harvard University, awarded in 2010. His doctoral research focused on the integration of renewable energy sources and the development of large-scale energy systems models. He also earned a Master of Science in Applied Mathematics from Harvard University, which provided him with a robust analytical foundation to address complex energy and environmental challenges. Prior to his graduate studies, Professor Lu completed his Bachelor of Science degree in Environmental Science at Tsinghua University. His interdisciplinary academic background, combining engineering, mathematics, and environmental science, has equipped him with a unique skill set to tackle multifaceted problems in energy systems and sustainability.

Professional Experience

Professor Xi Lu currently serves as a full professor at Tsinghua University, where he leads advanced research in renewable energy systems, carbon mitigation strategies, and environmental policy modeling. Prior to this role, he held a research fellowship at Harvard University, where he contributed to groundbreaking studies on renewable energy integration and grid stability. Professor Lu has also collaborated with international organizations and government agencies, providing data-driven insights for shaping renewable energy policies. His professional career spans over two decades, during which he has led interdisciplinary research projects, supervised doctoral candidates, and facilitated industry-academic partnerships. His expertise is sought after globally, and he frequently participates in high-level discussions on energy policy and sustainable development.

Research Interests

Professor Xi Lu’s research interests revolve around renewable energy systems, carbon neutrality, and environmental systems modeling. He is particularly focused on developing advanced computational models to evaluate and optimize the performance of large-scale renewable energy infrastructures. His work addresses key issues such as integrating renewable energy into national grids, enhancing energy efficiency, and reducing greenhouse gas emissions. Additionally, Professor Lu is interested in policy-oriented research that provides practical solutions to achieve sustainable energy transitions. He explores the intersection of technology, economics, and policy to inform and guide global energy strategies. His interdisciplinary approach allows him to tackle complex problems and develop innovative methodologies to assess environmental and economic trade-offs in energy systems.

Research Skills

Professor Xi Lu possesses a diverse set of research skills that encompass advanced computational modeling, quantitative analysis, and large-scale energy system simulations. He is proficient in developing and applying optimization algorithms to assess renewable energy integration and grid stability. His expertise extends to geospatial analysis, which he uses to evaluate the spatial distribution and potential of renewable energy resources. Additionally, Professor Lu is skilled in policy modeling and the use of statistical methods to analyze the economic and environmental impacts of energy systems. His ability to integrate engineering techniques with environmental science and applied mathematics allows him to develop comprehensive models that inform both academic research and practical policy decisions.

Awards and Honors

Throughout his career, Professor Xi Lu has received numerous prestigious awards and honors recognizing his contributions to renewable energy research and environmental sustainability. In 2020, he was awarded the National Science Fund for Distinguished Young Scholars, a testament to his innovative research and academic excellence. He also received the Youth Scientist Gold Award from the Chinese Society for Environmental Sciences. His achievements have been further recognized through the 15th China Youth Science and Technology Award. These accolades highlight Professor Lu’s significant impact on advancing renewable energy technologies and shaping energy policies. His research has also earned international acclaim, with several of his publications featured as cover articles in top-tier journals like Nature Energy and Science.

Conclusion

Professor Xi Lu stands out as a leading expert in renewable energy systems and environmental policy modeling. His groundbreaking research has advanced the understanding of renewable energy integration and informed sustainable energy policies worldwide. With a strong academic foundation, extensive professional experience, and an impressive track record of high-impact publications, Professor Lu continues to drive innovation and provide actionable solutions for global energy challenges. His work not only addresses current issues in energy sustainability but also paves the way for future advancements in carbon neutrality and renewable technology. Professor Lu’s interdisciplinary expertise, combined with his commitment to scientific excellence, makes him a deserving candidate for the Best Scholar Award in Research. His contributions are instrumental in shaping a sustainable and energy-secure future on a global scale.

Publication Top Notes

  1. The risk-based environmental footprints and sustainability deficits of nations

    • Authors: J. He, Jianjian; P. Zhang, Pengyan; X. Lu, Xi
    • Year: 2025

  2. High-resolution gridded dataset of China’s offshore wind potential and costs under technical change

    • Authors: K. An, Kangxin; W. Cai, Wenjia; X. Lu, Xi; C. Wang, Can
    • Year: 2025

  3. Unraveling climate change-induced compound low-solar-low-wind extremes in China

    • Authors: L. Wang, Licheng; Y. Liu, Yawen; L. Zhao, Lei; T. Zhu, Tong; Y. Qin, Yue
    • Year: 2025

  4. Global disparity in synergy of solar power and vegetation growth

    • Authors: S. Chen, Shi; Y. Wang, Yuhan; X. Lu, Xi; K. He, Kebin; J. Hao, Jiming
    • Year: 2025

  5. Evaluating global progress towards Sustainable Development Goal 7 over space and time by a more comprehensive energy sustainability index

    • Authors: Q. Zhao, Qi; X. Lu, Xi; R. Marie Fleming, Rachael
    • Year: 2025

  6. The 2023 report of the synergetic roadmap on carbon neutrality and clean air for China: Carbon reduction, pollution mitigation, greening, and growth

    • Authors: J. Gong, Jicheng; Z. Yin, Zhicong; Y. Lei, Yu; J. Wang, Jinnan; K. He, Kebin
    • Year: 2025

  7. The future of coal-fired power plants in China to retrofit with biomass and CCS: A plant-centered assessment framework considering land competition

    • Authors: Y. Sun, Yunqi; A. Deng, An; Q. Yang, Qing; H. Yang, Haiping; H. Chen, Hanping
    • Year: 2025
    • Citations: 1

  8. Assessing the synergies of flexibly-operated carbon capture power plants with variable renewable energy in large-scale power systems

    • Authors: J. Li, Jiacong; C. Zhang, Chongyu; M.R. Davidson, Michael R.; X. Lu, Xi
    • Year: 2025
    • Citations: 1

  9. Synergies of variable renewable energy and electric vehicle battery swapping stations: Case study for Beijing

    • Authors: C. Zhang, Chongyu; X. Lu, Xi; S. Chen, Shi; A.M. Foley, Aoife M.; K. He, Kebin
    • Year: 2024
    • Citations: 1

  10. Correction to: Assessing global drinking water potential from electricity-free solar water evaporation device

  • Authors: W. Zhang, Wei; Y. Chen, Yongzhe; Q. Ji, Qinghua; H. Liu, Huijuan; J. Qu, Jiuhui
  • Year: 2024

Pingwei Zheng | Energy | Best Researcher Award

Published on by Shen Awards

Prof. Dr. Pingwei Zheng | Energy | Best Researcher Award

College teachers at University of South China, China

Prof. Dr. Pingwei Zheng, a distinguished physicist at the University of South China, specializes in RF heating and current drive in magnetic confinement fusion devices, focusing on the Ohkawa mechanism and synergy effects among electron cyclotron, high harmonic fast wave, and lower hybrid current drive methods. With a Ph.D. in Nuclear Fusion and Plasma Physics from USC, he has published extensively in leading journals, including Nuclear Fusion and Physics of Plasmas. His pioneering contributions, such as developing new mechanisms for current drive and synergy effects in plasma, have significantly advanced nuclear fusion research. Dr. Zheng has led multiple research projects funded by the National Natural Science Foundation of China and other provincial initiatives, showcasing his expertise in both theoretical and computational approaches. His technical proficiency, academic leadership, and innovative work position him as a leading figure in the field, contributing meaningfully to the global pursuit of sustainable fusion energy.

Professional Profile

Education

Professor Dr. Pingwei Zheng has a robust academic foundation in physics and nuclear fusion. He earned his Bachelor’s degree in Physics from Hunan Normal University, Changsha, in 2006. Driven by a passion for advanced research, he pursued postgraduate studies at the University of South China (USC), Hengyang, where he completed his Master’s degree in 2011, specializing in nuclear fusion and plasma physics. During this time, he developed a 3D Fokker-Planck code for RF heating and current drive using Fortran, laying the groundwork for his future contributions to fusion research. Building on his expertise, he obtained his Ph.D. in Nuclear Fusion and Plasma Physics from USC in 2019. His doctoral work focused on innovative mechanisms like Ohkawa-current-driven electron cyclotron waves and synergy effects in magnetic confinement fusion. This extensive academic journey reflects Dr. Zheng’s commitment to advancing the field of plasma physics and nuclear fusion technology.

Professional Experience

Prof. Dr. Pingwei Zheng is a distinguished physicist specializing in RF heating and current drive in magnetic confinement fusion devices. Since 2011, he has been a faculty member at the University of South China (USC), where he has led groundbreaking research on the Ohkawa mechanism-dominated current drive (OKCD) of electron cyclotron waves and the synergy effects between OKCD, high harmonic fast wave (HHFW), and lower hybrid current drive (LHCD). Dr. Zheng has successfully managed two projects funded by the National Natural Science Foundation of China and several provincial and ministerial-level research initiatives. His earlier work as a postgraduate included developing a 3D Fokker-Planck code for RF heating and current drive, showcasing his technical expertise in computational physics. Over the years, he has contributed significantly to advancing nuclear fusion research through his innovative studies, impactful publications in top-tier journals, and dedication to advancing fusion energy technologies.

Research Interest

Prof. Dr. Pingwei Zheng’s research is centered on advancing the understanding and development of RF heating and current drive mechanisms in magnetic confinement fusion devices. His work focuses on electron cyclotron current drive (ECCD), high harmonic fast wave (HHFW) current drive, and lower hybrid current drive (LHCD), with particular emphasis on the Ohkawa mechanism-dominated current drive (OKCD) and its synergy effects with other RF techniques. He has conducted innovative studies on the interaction of RF waves with plasma, including the stabilization of neoclassical tearing modes and enhancing current drive efficiency in the pedestal region of high-confinement tokamak plasmas. Prof. Zheng’s contributions extend to developing numerical methods and computational tools to simulate these phenomena, such as 3D Fokker-Planck codes. His research aims to address critical challenges in achieving sustainable fusion energy, positioning his work at the forefront of plasma physics and nuclear fusion technology.

Award and Honor

Prof. Dr. Pingwei Zheng, a distinguished researcher in nuclear fusion and plasma physics, has earned recognition for his groundbreaking contributions to RF heating and current drive in magnetic confinement fusion devices. As a principal investigator, he has successfully led multiple prestigious projects funded by the National Natural Science Foundation of China and provincial and ministerial-level bodies. His innovative research on the Ohkawa mechanism-dominated current drive (OKCD) and the synergy effects between RF current drive methods has been widely acclaimed. Dr. Zheng’s prolific academic output includes publications in high-impact journals such as Nuclear Fusion and Physics of Plasmas, showcasing his expertise and influence in the field. As a professor at the University of South China, he has become a leading voice in advancing theoretical and applied research in fusion technology, earning accolades for his commitment to scientific innovation and his contributions to the global energy research community.

Conclusion

Prof. Dr. Pingwei Zheng is a distinguished researcher whose work in nuclear fusion and plasma physics demonstrates significant innovation and technical mastery. His specialized research on RF heating and current drive mechanisms, particularly the Ohkawa mechanism and synergy effects, has made valuable contributions to the advancement of magnetic confinement fusion technology. With a strong academic background, numerous publications in high-impact journals, and leadership in nationally funded projects, Dr. Zheng has established himself as a leader in his field. His expertise in computational modeling and numerical methods further enhances the practical and theoretical depth of his research. While expanding his global collaborations and highlighting broader community engagement could strengthen his profile further, Dr. Zheng’s achievements clearly reflect his dedication to addressing critical challenges in fusion energy. His contributions make him a deserving and competitive candidate for the Best Researcher Award.

Publications Top Noted

  1. Numerical investigation of electron cyclotron and electron Bernstein wave current drive in EXL-50U spherical torus
  2. Numerical study of minority ion heating scenarios in CN-H1 stellarator plasma
  3. Numerical Studies on Electron Cyclotron Resonance Heating and Optimization in the CN-H1 Stellarator
  4. Impact of hot plasma effects on electron cyclotron current drive in tokamak plasmas
  5. A full wave solver integrated with a Fokker–Planck code for optimizing ion heating with ICRF waves for the ITER deuterium–tritium plasma
  6. Evaluation of ECCD power requirement for neoclassical tearing modes suppression in the CFETR hybrid scenario
  7. Integrated simulation analysis of the HL-2M high-parameter hybrid scenario
  8. Separate calculations of the two currents driven by electron cyclotron waves
  9. Electron cyclotron current drive under neutral beam injection on HL-2M
  10. Numerical study of m = 2/n = 1 neoclassical tearing mode stabilized by the Ohkawa-mechanism-dominated current drive of electron cyclotron waves
  11. Numerical investigation of ECCD under the CFETR concept design parameters
  12. Effective current drive in the pedestal region of high-confinement tokamak plasma using electron cyclotron waves
  13. New synergy effects of the lower hybrid wave and the high harmonic fast wave current drive
  14. Simulation of plasma scenarios for CFETR phase II based on engineering design parameters
  15. Numerical investigation of a new ICRF heating scenario in D-T plasma on CFETR
  16. Simulation of the Ohkawa-mechanism- dominated current drive of electron cyclotron waves using linear and quasi-linear models