Shoulong Xu | Nuclear Radiation Detection | Best Researcher Award

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Dr. Shoulong Xu | Nuclear Radiation Detection | Best Researcher Award

University of South China, China

Shoulong Xu, born in June 1988, is an Associate Professor in the School of Resources, Environment and Safety Engineering at the University of South China. A member of the Communist Party of China, he holds a Doctorate in Engineering and supervises master’s students. Xu conducted his postdoctoral research at Tsinghua University and has built a prominent career in nuclear safety and radiation detection. He has authored over 50 academic papers, including significant publications in high-impact journals, and holds seven invention patents. He leads provincial-level demonstration courses and teams focused on integrating ideological and political education into engineering disciplines. Xu actively contributes to professional societies, serving on committees within the Chinese Nuclear Society and the Chinese Instrument and Control Society. His research emphasizes technologies for nuclear emergency safety, radiation-hardened systems, and monitoring solutions for extreme environments, advancing both scientific knowledge and practical safety standards in the nuclear sector.

Professional Profile

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Education 

Shoulong Xu embarked on his academic path in 2006 at North China Electric Power University, where he earned his Bachelor’s degree in Thermal Energy and Power Engineering in July 2010. Driven by a growing interest in nuclear technology, he continued his education at the University of South China from September 2011 to June 2017, pursuing a doctoral degree in Nuclear Technology and Applications under the supervision of Professor Shuliang Zou. His Ph.D. research focused on nuclear radiation detection and monitoring technologies essential for safety and emergency response in nuclear facilities. Following his doctorate, Xu undertook a prestigious postdoctoral fellowship from December 2017 to December 2019 at the Department of Engineering Physics, Tsinghua University. During this period, he deepened his expertise in radiation detection and radiation-hardened systems. This robust educational background has been foundational in establishing Xu as a leading researcher and educator in nuclear safety engineering and radiation technologies.

Professional Experience 

After earning his doctorate, Shoulong Xu began his academic career as a Lecturer in June 2017 at the University of South China’s School of Resources, Environment and Safety Engineering. In June 2021, he was promoted to Associate Professor. His administrative trajectory has been equally dynamic: he served as Deputy Director and subsequently Director of the Safety Engineering Department between 2021 and 2024. Xu then took on leadership roles as Vice Dean of the School of Resources, Environment and Safety Engineering and Vice Dean of the Graduate School from 2024 to early 2025. As of March 2025, he serves as Director of the Admissions Office and Career Guidance Center at the University of South China. Parallel to these administrative positions, Xu conducted postdoctoral research at Tsinghua University from 2017 to 2019. Throughout his career, he has combined research, teaching, and leadership, making significant contributions to nuclear safety and engineering education.

Awards and Honors

Shoulong Xu’s excellence in research and education has earned him significant recognition. He was selected as a Young Scholar under Hunan Province’s Furong Scholars Program, highlighting his potential and achievements in scientific innovation. Xu has been honored as a Model Teacher for Ideological and Political Education in Courses in Hunan Province, reflecting his dedication to integrating ideological values into technical education. He leads both a Model Teaching Team and a Model Course for Ideological and Political Education in the province, showcasing his influence in academic reform. Additionally, he directs a Demonstration Course for Graduate Students in Hunan Province. Professionally, he serves as a committee member of the Youth Committee of the Chinese Nuclear Society and the Nuclear Instrumentation and Control Technology Branch of the Chinese Instrument and Control Society. He is also Deputy Director of two major provincial research centers, underscoring his leadership in advancing nuclear safety technologies and education.

Research Interests

Shoulong Xu’s research interests lie at the intersection of nuclear safety, radiation detection, and emergency technologies. He specializes in nuclear radiation detection and monitoring systems designed for extreme environments, including high-radiation fields and complex operational conditions. His work focuses on developing nuclear emergency safety technologies and equipment, ensuring timely and precise responses to nuclear incidents. Another key area of his research is radiation-hardened reinforcement techniques, aiming to enhance the durability and reliability of sensing and control systems used in nuclear robots and facilities. Xu is deeply involved in studying nuclear facility decommissioning and spent fuel reprocessing safety, working on risk assessment and innovative monitoring approaches. His projects often combine cutting-edge sensor technologies, advanced algorithms for real-time data processing, and robust system engineering to address the challenges posed by nuclear accidents and radiation hazards, contributing both to national defense needs and civilian nuclear safety enhancements.

Research Skills 

Shoulong Xu possesses a robust set of research skills essential for advancing nuclear safety technologies. He is proficient in nuclear radiation detection methods, including using monolithic active pixel sensors (MAPS) and commercial off-the-shelf (COTS) CMOS sensors for both low- and high-dose-rate environments. Xu is skilled in radiation-hardening techniques, ensuring electronic systems can function reliably under intense radiation exposure. His expertise extends to atmospheric diffusion modeling using tools like CALPUFF, applied to simulate radionuclide dispersion in nuclear incidents. Xu is adept at risk assessment methodologies for nuclear facilities, including dynamic fault tree analysis and socio-technical modeling of accident scenarios. He has strong capabilities in real-time data acquisition, signal processing, and parallel computing for optimizing radiation monitoring systems. Xu also demonstrates proficiency in hardware-software integration for radiation detection equipment. His experience spans both fundamental research and collaborative industrial projects, combining theoretical analysis with practical system development for nuclear safety applications.

Publication Top Notes

  • Research on Radiation Damage and Reinforcement of Control and Sensing Systems in Nuclear Robots. Electronics 2024, 13, 1214.

  • Study on the Atmospheric Diffusion of Airborne Radionuclide under LOCA of Offshore Floating Nuclear Power Plants Based on CALPUFF. Sustainability 2023, 15(3): 2572.

  • Risk Analysis and Evaluation of Nuclear Security Radiation Events in Spent Fuel Reprocessing Plants. Sustainability 2023, 15(1): 781.

  • Parallel processing of radiation measurements and radiation video optimization. Optics Express 2022, 30(26): 46870-46887.

  • Evaluation of Emergency Response Measures for the LOCA of A Marine Reactor. Sustainability 2022, 14(21): 13873.

  • Research on Calculation Method of Radiation Response Eigenvalue of a Single-Chip Active Pixel Sensor. Sensors 2022, 22(13): 4815.

  • Real-time monitoring method for radioactive substances using monolithic active pixel sensors (MAPS). Sensors 2022, 22(10): 3919.

  • Strong Radiation Field Online Detection and Monitoring System with Camera. Sensors 2022, 22(6): 2279.

  • Ultrawide-range radiation detection based on dynamic identification and analysis of the response of a monolithic active pixel sensor. Optics Express 2022, 30: 14134-14145.

  • Safety analysis of marine nuclear reactor in severe accident with dynamic fault trees based on cut sequence method. Nuclear Engineering and Technology 2022, 54(12): 4560-4570.

  • Effect analysis of break size on source term release and radioactive consequences of marine nuclear reactor during loss of coolant accident. Energy Research 2022, 46(15): 23715-23729.

  • A Novel Approach for Radionuclide Diffusion in the Enclosed Environment of a Marine Nuclear Reactor During a Severe Accident. Nuclear Science and Techniques 2022, 33(2): 1-13.

  • Low dose rate γ-ray detection using a MAPS camera under a neutron radiation environment. Optics Express 2021, 29(22): 34913-34925.

  • Obtaining High Dose rate γ-ray Detection with Commercial off-the-shelf CMOS Pixel Sensor Module. IEEE Sensors Journal 2019, 19(16): 6729.

  • Video Monitoring Application of CMOS 4T-PPD-APS Under γ-ray Radiation. Sensors 2019, 19(3): 359.

  • Effect of Commercial Off-The-Shelf MAPS on γ-Ray Ionizing Radiation Response to Different Integration Times and Gains. Sensors 2019, 19(22): 4950.

  • Study on the Availability of 4T-APS as a Video Monitor and Radiation Detector in Nuclear Accidents. Sustainability 2018, 10(7): 2172.

  • Radionuclide Transfer in the Zirconium Oxychloride Production Process and the Radiation Effect in a Typical Chinese Enterprise. Sustainability 2019, 11(21): 5906.

  • γ-ray Detection Using Commercial Off-The-Shelf CMOS and CCD Image Sensors. IEEE Sensors Journal 2017, 17(20): 6599-6604.

  • Study on Release and Migration of Radionuclides Under the Small Break Loss of Coolant Accident in a Marine Reactor. Science and Technology of Nuclear Installations.

Assist. Prof. Dr. Abdul Kabir Khan | Nuclear Reaction | Best Researcher Award

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Assist. Prof. Dr. Abdul Kabir Khan | Nuclear Reaction | Best Researcher Award

Assist. Prof. Dr. Abdul Kabir Khan | Nuclear Reaction | Assistant Professor at Institute of Space Technology Islamabad 44000, Pakistan

Dr. Abdul Kabir Khan is an Assistant Professor of Physics at the Department of Space Science, Institute of Space Technology, Islamabad, Pakistan. He specializes in Theoretical Nuclear Astrophysics, focusing on nucleosynthesis, stellar evolution, weak interaction rates, and nuclear spectroscopy. He has made significant contributions to radiative capture reactions, nuclear dynamics, and cross-section analysis. With a Ph.D. from GIK Institute, his work is widely recognized in nuclear astrophysics and plasma physics. Dr. Khan has received multiple Gold Medals for academic excellence and serves as a reviewer for prestigious journals, including Nuclear Physics A and Scientific Reports. His expertise extends to computational physics, utilizing tools like Matlab, Mathematica, and Fortran. As a HEC-approved supervisor, he actively mentors students in quantum mechanics, nuclear physics, and astrophysics. His research has earned him the Young Scientist Award (2023) in AI & Robotics, showcasing his diverse scientific contributions.

Professional Profile :         

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Summary of Suitability for Award:

Dr. Abdul Kabir Khan is a distinguished researcher in Theoretical Nuclear Astrophysics, with a strong academic background and a robust publication record. His research spans crucial areas such as nucleosynthesis, nuclear reactions, stellar evolution, and quantum many-body physics. With expertise in nuclear shape transitions, weak interaction rates, and radiative capture reactions, his work significantly contributes to understanding astrophysical processes. He has demonstrated excellence in scientific research, evident from his H-index and multiple citations. His role as an HEC-approved supervisor and reviewer for renowned journals further underscores his academic contributions. His consistent recognition through prestigious awards, including gold medals, young scientist awards, and best project supervision awards, highlights his dedication to scientific advancement. Dr. Abdul Kabir Khan’s research excellence, academic impact, and contributions to nuclear astrophysics make him an outstanding candidate for the “Best Researcher Award.” His innovative research, leadership in mentoring, and active role in peer review showcase his significant influence in the scientific community. His achievements align with the criteria for this prestigious award, making him a highly deserving nominee.

🎓Education:

Dr. Abdul Kabir Khan holds a Ph.D. in Theoretical Nuclear Astrophysics from GIK Institute, Topi, Pakistan, where his research focused on the theoretical study of nuclear processes within the CNO cycle. He earned his MS in Theoretical Nuclear Astrophysics from the same institution, specializing in radiative proton capture by carbon at low energy, achieving a high GPA and earning a gold medal. He completed his M.Sc. in Theoretical Physics from Abdul Wali Khan University Mardan with distinction, securing another gold medal. His undergraduate studies in Physics, Mathematics, and Electronics were also completed at Abdul Wali Khan University Mardan, where he demonstrated academic excellence by securing top positions. His early education includes F.Sc. in Pre-Engineering and Biology and SSC in Sciences from BISE Mardan and BISE Peshawar, where he performed exceptionally well. Throughout his academic journey, he maintained an outstanding record, achieving top rankings and multiple gold medals.

🏢Work Experience:

Dr. Abdul Kabir Khan is an Assistant Professor in the Department of Space Science at the Institute of Space Technology, Islamabad. His teaching expertise spans a wide range of graduate-level courses, including advanced quantum mechanics, theoretical astrophysics, nuclear physics, and computational physics. In addition to his teaching responsibilities, he has served as a research assistant and graduate assistant during his Ph.D. and MS studies. He has successfully guided final-year research projects, receiving multiple awards for outstanding project supervision. His role extends beyond teaching, as he is an HEC-approved supervisor, mentoring graduate students in nuclear astrophysics and theoretical physics. His contributions as a reviewer for reputed journals such as Journal of Nuclear Physics A, Scientific Reports, and Advances in Space Research highlight his active involvement in the academic community. His expertise in scientific computing, including MATLAB, LaTeX, and Fortran, further strengthens his ability to conduct and support high-level research.

🏅Awards: 

Dr. Abdul Kabir Khan has received numerous prestigious awards throughout his academic and professional career. He secured multiple gold medals for academic excellence in MS, M.Sc., and B.Sc., demonstrating his outstanding scholarly achievements. He has been honored with the Young Scientist Award for contributions to AI and Robotics. As a faculty member, he has consistently received the Best Final Year Project Award for mentoring exceptional research work at the Institute of Space Technology. His contributions to research and academia have also earned him recognition as an HEC-approved supervisor. Additionally, his early academic excellence was acknowledged when he secured first position in SSC sciences. He has actively contributed as a reviewer for renowned international journals, further establishing his credibility in the research community. His commitment to scientific advancement and education has been recognized by multiple institutions, reflecting his dedication to innovation and knowledge dissemination.

🔬Research Focus:

Dr. Abdul Kabir Khan’s research interests encompass a broad spectrum of theoretical nuclear astrophysics and quantum many-body physics. His work explores nucleosynthesis problems, including r-, s-, p-, and rp-processes, focusing on the evolution of stars and supernova explosions. He investigates nuclear shape transitions, nuclear dynamics, and ground-state properties, along with weak interaction rates in stellar environments. His expertise extends to atomic and nuclear spectroscopy, radiative capture reactions, and low-energy neutron physics. His studies delve into theoretical plasma physics and nonlinear problems in mathematical and physical sciences. He has made significant contributions to understanding nuclear branching points and nuclear cross-sections, providing valuable insights into the mechanisms governing astrophysical processes. His multidisciplinary approach integrates advanced computational methods, contributing to advancements in nuclear theory and space sciences. His work plays a crucial role in bridging the gap between nuclear physics and astrophysical phenomena, enhancing our understanding of cosmic processes.

Publication Top Notes:

Radiative capture of proton by at low energy

Citations: 16

Ion-scale solitary waves in magnetoplasma with non-thermal electrons

Citations: 15

Nonlinear periodic structures in nonthermal magnetoplasma with the presence of pressure anisotropy

Citations: 14

The nuclear ground-state properties and stellar electron emission rates of 76Fe, 78Ni, 80Zn, 126Ru, 128Pd and 130Cd using RMF and pn-QRPA models

Citations: 14

Radiative capture of proton by at low energy

Citations: 13

Proton Capture Cross-section for 12C at Low Energy

Citations: 12

Oblique propagation of ion-acoustic solitary waves in magnetized electron-positron-ion plasma with Cairns distribution

Citations: 10

Re-examination of astrophysical S-factor of proton capture Be9 (p, γ) 10B in stellar matter

Citations: 10

Radiative capture of proton by 9Be (p, γ) 10B at low energy

Citations: 8

On the shock wave structures in anisotropy magnetoplasmas

Citations: 7

 

Dr. YongDeok Lee | Nuclear engineering | Best Researcher Award

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Dr. YongDeok Lee | Nuclear engineering | Best Researcher Award

Dr. YongDeok Lee | Nuclear engineering | Principal researcher at KAERI , South Korea

Dr. YongDeok Lee is a Principal Researcher at the Korea Atomic Energy Research Institute (KAERI), specializing in nuclear material assay, spent fuel management, and nuclear safeguards. With expertise in neutron and gamma detection, fissile assay technology, and nuclear waste analysis, he has significantly contributed to the development of advanced nuclear monitoring methods. He also delivers nuclear measurement lectures at universities, shaping the next generation of nuclear scientists. His pioneering research focuses on spent fuel fissile assay and nuclear monitoring, ensuring the safe handling and security of nuclear materials. Dr. Lee has led numerous consultancy and industry projects, with 10 successful collaborations in nuclear measurement and safety. His contributions are recognized in SCI-indexed journals, particularly in Nuclear Engineering and Technology. With a commitment to advancing nuclear safeguards, he has proposed and developed innovative nuclear monitoring technologies, making a significant impact on global nuclear safety and security.

Professional Profile :         

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Summary of Suitability for Award:

Dr. YongDeok Lee, a Principal Researcher at the Korea Atomic Energy Research Institute (KAERI), is an outstanding candidate for the “Best Researcher Award” due to his extensive contributions to nuclear material assay, spent fuel management, and nuclear safeguards. His pioneering research in neutron and gamma detection, fissile material measurement, and nuclear monitoring has played a crucial role in advancing nuclear safety and security. With multiple SCI-indexed publications, 10 successful consultancy projects, and notable contributions to nuclear waste analysis, Dr. Lee has demonstrated exceptional expertise and innovation in the field of nuclear engineering. His work in developing isotopic fissile assay technology has had a significant impact on global nuclear safeguards. Dr. YongDeok Lee’s outstanding research achievements, technological innovations, and commitment to nuclear safety make him a highly suitable candidate for the “Best Researcher Award”. His groundbreaking advancements in nuclear monitoring and safeguards technology have contributed significantly to the scientific community and industry. Recognizing his contributions with this award would acknowledge his exceptional dedication and impact in the field of nuclear engineering and security.

🎓Education:

Dr. YongDeok Lee holds an advanced academic background in nuclear engineering, with specialized training in nuclear material measurement, neutron generation, and nuclear safeguards. His expertise was honed through rigorous academic coursework and practical applications in nuclear science. He pursued his higher education in nuclear engineering, focusing on spent fuel analysis, fissile material characterization, and neutron/gamma detection techniques. His research contributions in nuclear safeguards and waste management have been instrumental in shaping nuclear security policies and technologies. Through academic collaborations and industry-driven projects, he has expanded his knowledge in nuclear monitoring and safety mechanisms. His educational foundation has equipped him with the necessary skills to lead cutting-edge research in nuclear fuel analysis and radiation detection methodologies. Additionally, his role as a nuclear measurement lecturer has allowed him to share his expertise, mentoring young scientists and fostering advancements in the field of nuclear engineering.

🏢Work Experience:

Dr. YongDeok Lee has extensive experience in nuclear material assay, spent fuel analysis, and nuclear waste management. As a Principal Researcher at KAERI, he has worked on fissile measurement in spent fuel, neutron and gamma detection, and nuclear safeguards. His expertise spans nuclear monitoring for spent fuel security, contributing to the development of advanced nuclear measurement techniques. He has successfully led 10 consultancy and industry projects, collaborating with international nuclear institutions. His work involves the design and implementation of nuclear monitoring systems, ensuring compliance with global nuclear safety standards. Dr. Lee is also an experienced nuclear measurement lecturer, training the next generation of nuclear professionals in neutron generation, radiation detection, and nuclear waste analysis. His research in spent fuel fissile assay and nuclear security has been widely recognized, with multiple publications in SCI-indexed journals. His contributions to nuclear safeguards technology continue to shape the future of nuclear security.

🏅Awards: 

Dr. YongDeok Lee has been recognized for his exceptional contributions to nuclear engineering and safeguards technology. He has received multiple accolades, including awards for innovation in nuclear material assay and nuclear monitoring. His work on fissile measurement technology for spent fuel has earned him recognition from leading nuclear research institutions. As an esteemed researcher, he has contributed to SCI-indexed publications, particularly in Nuclear Engineering and Technology, further solidifying his reputation in the scientific community. He is a recipient of the Best Researcher Award, acknowledging his significant achievements in nuclear waste analysis and spent fuel management. His international collaborations and industry consultancy projects have also brought him recognition in nuclear safeguards and security research. Through his dedication to developing advanced nuclear monitoring systems, Dr. Lee continues to receive accolades for his groundbreaking work in nuclear material safety, radiation detection, and spent fuel fissile assay.

🔬Research Focus:

Dr. YongDeok Lee’s research revolves around nuclear material assay, spent fuel fissile assay, and nuclear waste analysis. His primary focus is on developing innovative technologies for nuclear monitoring and safeguards. His work in fissile measurement of spent fuel ensures efficient and secure handling of nuclear materials, contributing to global nuclear safety efforts. He specializes in neutron and gamma detection techniques, applying them to nuclear waste management and radiation monitoring. His research also extends to technology development for nuclear safeguards, ensuring strict compliance with international nuclear security protocols. Through his expertise in spent fuel management, he has proposed and developed advanced nuclear monitoring technologies for better regulatory control and security enforcement. Dr. Lee’s research contributions are widely published in SCI-indexed journals, particularly in Nuclear Engineering and Technology. His innovations in isotopic fissile assay technology continue to advance nuclear security and monitoring systems worldwide.

Publication Top Notes:

Feasibility of Nuclear Monitoring for Pyro-process Using Radiation Measurement

Radiation Monitoring of Nuclear Material in Process for Reducing Environmental Burden

Fissile Measurement in Various Types Using Nuclear Resonances

Sensitivity Simulation on Isotopic Fissile Measurement Using Neutron Resonances

Nuclear Measurement in Pyro-processed Wastes

Isotopic Fissile Assay of Spent Fuel in a Lead Slowing-Down Spectrometer System

Development of Lead Slowing Down Spectrometer for Isotopic Fissile Assay

Design of LSDS for Isotopic Fissile Assay in Spent Fuel