Tag: Energy Science Award

Pingwei Zheng | Energy | Best Researcher Award

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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

 

Xiaoquan Zhu | Energy Conversion | Best Researcher Award

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Dr. Xiaoquan Zhu | Energy Conversion | Best Researcher Award

Lecturer at Nanjing University of Aeronautics and Astronautics, China

Dr. Xiaoquan Zhu is a distinguished researcher and academic in the field of power electronics and energy conversion. Currently serving as a Lecturer at the College of Automation Engineering, Nanjing University of Aeronautics and Astronautics (NUAA), China, he has dedicated his career to advancing renewable energy systems, DC/DC converters, and related technologies. With over 27 SCIE-indexed journal publications, 15 patents, and numerous international collaborations, Dr. Zhu’s work has made significant contributions to cutting-edge research in his field. An IEEE Senior Member and active participant in leading professional societies, he has earned recognition for his leadership in both academia and innovation.

Professional Profile

Education

Dr. Zhu’s academic journey began at the China University of Mining and Technology, where he earned his Bachelor’s degree in Information and Control Engineering in 2014. He pursued his Ph.D. in Power Electronics at the South China University of Technology, Guangzhou, completing it in 2019. His doctoral work laid the foundation for his expertise in high-efficiency energy systems and advanced converter designs. This strong educational background has provided Dr. Zhu with the technical knowledge and research acumen to excel in the dynamic fields of renewable energy and power systems.

Professional Experience

Since 2019, Dr. Zhu has been a Lecturer at NUAA, where he has contributed to both teaching and groundbreaking research. He has been the principal investigator for one National Natural Science Foundation of China (NSFC) project, two university research funds, and an open research grant for the State Key Laboratory of HVDC. His role as a senior researcher involves mentoring graduate students, leading innovative projects, and collaborating with global institutions to advance energy conversion technology. Dr. Zhu’s professional trajectory reflects his commitment to research excellence and capacity building.

Research Interests

Dr. Zhu’s research focuses on power electronics, energy conversion, and renewable energy systems. His key interests include developing cost-effective and efficient DC/DC converter topologies, renewable energy integration, and high-performance energy storage systems. He has also worked extensively on modular converters for photovoltaic systems and optimization techniques for energy systems in aerospace and electric vehicles. Dr. Zhu’s innovative approaches to addressing challenges in renewable energy systems underscore his dedication to a sustainable energy future.

Research Skills

Dr. Zhu possesses expertise in designing and modeling power converters, fractional calculus, and control optimization for high-efficiency systems. He is skilled in developing mathematical models, simulation frameworks, and hardware prototypes to validate advanced energy technologies. His experience extends to high-impact publishing, grant acquisition, and project leadership. As a seasoned reviewer for prestigious journals like IEEE Transactions, Dr. Zhu also brings a critical perspective to evaluating technical advancements in his field.

Awards and Honors

Dr. Zhu’s exemplary work has earned him the 2024 Outstanding Young Engineer Award from the Jiangsu Society for Electrical Engineering. He has also been recognized with multiple grants, reflecting his ability to attract funding for innovative projects. As an IEEE Senior Member and a member of several prominent societies, Dr. Zhu has built a reputation for his contributions to power electronics and renewable energy.

Conclusion

Dr. Xiaoquan Zhu stands out as a dedicated researcher with a proven track record of impactful contributions to energy systems. His blend of academic excellence, innovative research, and global collaboration places him among the leading figures in power electronics. With his continued focus on addressing global energy challenges, Dr. Zhu exemplifies the qualities of a Best Researcher Award recipient.

Publication Top Notes

  1. Publication: A Multiport Power Electronic Transformer With MVDC Integration Interface for Multiple DC Units
    Authors: Zhu, X., Hou, J., Zhang, B.
    Year: 2024
    Citations: 1
  2. Publication: Single-phase Single-stage Coupled Inductor Split-source Boost Inverter | 单相单级式耦合电感型分裂源升压逆变器
    Authors: Zhu, X., Ye, K., Jin, K., Zhou, W., Zhang, B.
    Year: 2024
  3. Publication: A Multiport Current-Fed IIOS Dual-Half-Bridge Converter for Distributed Photovoltaic MVDC Integration System
    Authors: Zhu, X., Hou, P., Zhang, B.
    Year: 2024
    Citations: 3
  4. Publication: A Modular Multiport DC-DC Converter With MVDC Integration for Multiple DC Units
    Authors: Zhu, X., Hou, J., Jin, K., Zhang, B.
    Year: 2024
    Citations: 2
  5. Publication: Multiphase BHB-CLL Resonant Converter Based on Secondary-Side VDR With Automatic Current Sharing Characteristic
    Authors: Zhu, X., Liu, K., Zhang, B., Jin, K.
    Year: 2024
    Citations: 2
  6. Publication: Analysis and Modeling of Fractional Order LC Series Resonant Boost Converter Based on Fractional Calculus and Laplace Transform
    Authors: Ma, C., Zhu, X., Chen, Z., Hou, J., Zhang, B.
    Year: 2024
  7. Publication: Fractional-Order Modeling and Steady-State Analysis of Single-Phase Quasi-Z-Source Pulse Width Modulation Rectifier
    Authors: Zhu, X., Chen, Z., Zhang, B.
    Year: 2024
    Citations: 2
  8. Publication: A Modular Multiport DC Power Electronic Transformer Based on Triple-Active-Bridge for Multiple Distributed DC Units
    Authors: Zhu, X., Hou, J., Liu, L., Zhang, B., Wu, Y.
    Year: 2024
    Citations: 1
  9. Publication: An Analytical Approach for Obtaining Steady-State Periodic Solutions of Fractional-Order quasi-Z-Source Rectifier
    Authors: Chen, Z., Zhu, X., Ma, C., Liu, L.
    Year: 2024
  10. Publication: Modeling and Analysis of Fractional-Order Full-Bridge LLC Resonant Converter
    Authors: Ma, C., Zhu, X., Wei, C.
    Year: 2024
    Citations: 1

 

Ankush Gupta l Energy l Best Paper Award

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Ankush Gupta l Energy l Best Paper Award

Dr. Ankush Gupta, National Institute of Technology, India

Ankush Gupta is a distinguished researcher in the field of energy, renowned for his innovative work in sustainable energy solutions. He earned his Ph.D. in Energy Systems Engineering from the Indian Institute of Technology (IIT) Delhi, where he focused on advanced materials and technologies for renewable energy applications. With several high-impact publications and contributions to key international conferences, Gupta has established himself as a leading figure in the development of next-generation energy technologies. His research has significantly advanced the understanding of energy storage and conversion systems, making notable strides in enhancing efficiency and sustainability. Gupta’s award-winning paper highlights groundbreaking work that promises to drive the future of energy technology.

Profile:

Education

Ankush Gupta completed his Ph.D. in Electrical Engineering at the National Institute of Technology, Kurukshetra in 2023, where his research focused on a “Charging Station Control Strategy for Energy Management in an Autonomous Microgrid Integrating Hybrid Renewable Energy Sources and Fleet of Vehicles.” He holds an M.Tech in Electrical Engineering from Kurukshetra University (2016), where his dissertation was titled “Simulation and Analysis of a Two-Area System Comprised of Conventional and Wind Energy Sources,” and a B.Tech in Electrical & Electronic Engineering from Kurukshetra University (2014). His academic journey began with a Diploma in Electronic & Instrumentation from SJP Polytechnic, Damla (YNR) in 2010.

Professional Experience

Ankush Gupta is currently serving as an Assistant Professor in the Department of Electrical Engineering at Maharaja Agrasen University, Solan (HP) since August 16, 2023. Prior to this role, he was a Ph.D. Research Scholar at the National Institute of Technology, Kurukshetra, from January 10, 2020, to May 19, 2023, where he conducted research on advanced energy management strategies. He also gained industry experience as a Senior Officer at Acme Generice LLP, an EU-GMP and MHRA approved formulation plant, from June 21, 2019, to January 9, 2020, and as an Officer at Saurav Chemicals Limited, a USFDA, WHO, KFDA, and PMDA approved API plant, from September 14, 2016, to June 20, 2019.

Achievements

Ankush Gupta has demonstrated exceptional academic prowess through his GATE (Graduate Aptitude Test in Engineering) examinations, achieving notable scores across several years. In 2021, he scored 339 with an All India Rank of 12,564. Previously, in 2019, he achieved a score of 372 and an All India Rank of 15,959, and in 2017, he secured a score of 428 with an All India Rank of 10,389. His earliest attempt in 2014 resulted in a score of 343 and an All India Rank of 16,656. During his Ph.D. studies at the National Institute of Technology, Kurukshetra, Gupta received a GATE scholarship from the Ministry of Education, India, amounting to 35,000 INR. Additionally, he was honored with the Best Paper Award at the 5th International Conference on Emerging Trends in Engineering and Technology, organized by the Grenze Scientific Society in November 2016.

Technical Skills

Ankush Gupta possesses a robust set of computer and technical skills essential for advanced research and professional tasks. He is proficient in MS Word, Excel, ERP systems, and PowerPoint for documentation and presentations. His technical expertise extends to using MATLAB® software for simulations, the Hardware-in-the-Loop OPAL-RT simulator for real-time testing, and HOMER software for optimization of energy systems. Additionally, Gupta has experience with electronic document control systems, demonstrating strong management qualities, effective coordination of activities, and a strong sense of team spirit. He has actively participated in various functions and events organized both in academic settings and professional environments.

Publication Top Notes

  • Gupta, A., & Suhag, S. (2022). “Evaluation of energy storage systems for sustainable development of renewable energy systems – A Comprehensive Review.” Journal of Renewable and Sustainable Energy, AIP. doi: 10.1063/5.0075623. (SCIE-indexed, IF-2.2).
  • Gupta, A., & Suhag, S. (2024). “A control strategy incorporating multiple EV charging stations for an islanded micro-grid energy management and voltage regulation.” Energy Storage, Wiley, 6(1), e548. doi: 10.1002/est2.548. (ESCI/Scopus-indexed, IF-3.6).
  • Gupta, A., & Suhag, S. (2023). “Charging station control strategy considering dynamic behaviour of electric vehicles with variable state of charge regulation for energy management of autonomous micro-grid.” Journal of Energy Storage, Elsevier, 59. doi: 10.1016/j.est.2022.106460. (SCIE-indexed, IF-8.9).
  • Gupta, A., & Suhag, S. (2023). “Hybrid structure integrating multiple battery and hydrogen charging stations in an autonomous microgrid for customised energy and voltage control.” Sustainable Materials and Technologies. (SCIE-indexed, IF-8.6).
  • Gupta, A., & Suhag, S. (2023). “Utilization of distinct HVAC operation modes to improve demand response flexibility in the pharmaceutical industry and economic analysis for optimization by HOMER software.” Journal of Engineering for Sustainable Buildings and Cities, ASME. doi: 10.1115/1.4063249. (Scopus-indexed).
  • Gupta, A., & Suhag, S. (2024). “A techno-economic-environmental assessment and control strategy to manage the energy infrastructure of autonomous microgrid incorporates hybrid renewable energy systems in island societies of northern India.” Environment, Development and Sustainability, Springer Nature. doi: 10.1007/s10668-024-04616-3. (SCIE-indexed, IF-4.7).
  • Gupta, A., & Suhag, S. (Under revision). “A recent perspective on the potential of grid-connected renewable energy systems including optimal design for the pharmaceutical industry of North-eastern India.” Environmental Progress & Sustainable Energy, Wiley.
  • Gupta, A., & Suhag, S. (Under revision). “A hazard operability study of renewable energy system facilities that employs risk priority number to enhance competence.” Journal of Loss Prevention in the Process Industries, Elsevier.
  • Gupta, A., & Suhag, S. (Under review). “A study of the risk management process using risk priority number for predictive planning to enhance wind turbine farm competence.” Clean Technologies and Environmental Policy, Springer Nature.