Jaeyoung Kwak | Interactions and fields | Best Researcher Award

Published on by High Energy Physics

Mr. Jaeyoung Kwak | Interactions and fields | Best Researcher Award

Korea Astronomy and Space Science Institute | South Korea

Jaeyoung Kwak is a passionate space physicist and Ph.D. candidate at the Korea Astronomy and Space Science Institute (KASI), specializing in space weather and radiation environments. With a strong foundation in shipbuilding engineering and a minor in history, he transitioned to the field of space science to pursue his deep interest in the cosmos. Jaeyoung has actively contributed to groundbreaking studies in magnetospheric wave-particle interactions, space radiation, and LEO satellite data analysis. Heโ€™s presented his work at prestigious global conferences and holds a notable publication record, combining technical proficiency, teaching experience, and international collaboration.

๐Ÿ‘จโ€๐ŸŽ“Profile

Scopus

๐Ÿ“˜ Early Academic Pursuits

Jaeyoungโ€™s academic journey began at Inha University, where he earned a B.S. in Shipbuilding Engineering, along with a minor in history. His early education focused on applied physics and engineering, equipping him with analytical thinking and structural understanding. His interest in natural sciences evolved into space research, prompting his enrollment in the University of Science and Technology (UST) โ€“ KASI School for a Ph.D. in Astronomy and Space Science, laying the groundwork for cutting-edge research.

๐Ÿ› ๏ธ Professional Endeavors

Before delving into academia, Jaeyoung worked as a Basic Design Engineer at HD Hyundai Heavy Industries, where he handled primary piping designs for commercial ships. Later, he became a full-time mathematics teacher at Myung Mathematics Academy, teaching students from middle school to high school. Since 2020, he has been working at KASI as a Ph.D. researcher in the Solar and Space Weather group. His diverse career path reflects strong interdisciplinary skills, hands-on engineering experience, and a commitment to education, all of which enrich his scientific perspective and research approach.

๐Ÿ”ฌ Contributions and Research Focus

Jaeyoung focuses on magnetospheric wave-particle interactions, space radiation analysis, and wave propagation phenomena, using both satellite and ground-based magnetometer data. He has contributed to key studies using the Arase satellite, analyzing EMIC and Pc1 waves, and their impact on Earthโ€™s radiation belts. His research extends to radiation dose modeling for aircrew, validating models like KREAM, CARI-7A, and NAIRAS using real-world flight data. His work strengthens global understanding of space weather hazards, with practical applications in aviation safety, satellite operation, and space mission planning.

๐ŸŒ Impact and Influence

Jaeyoung has shared his findings at global conferences like AGU, COSPAR, AOGS, and JpGU, strengthening Koreaโ€™s presence in international space science communities. His contributions help improve predictive models for space radiation, influencing both scientific inquiry and real-world safety protocols. Through his publications and international talks, heโ€™s established himself as a young researcher to watch. His cross-disciplinary insights from engineering, teaching, and astrophysics make his approach unique and highly impactful, advancing collaborative research in solar-terrestrial relationships and magnetospheric physics.

๐Ÿ“š Academic Cites

Jaeyoung has authored and co-authored multiple peer-reviewed journal articles, including in the Journal of Space Weather and Space Climate, and the Journal of Astronomy and Space Sciences. His first-author work explores Pc1 pulsation behavior during storm and non-storm conditions, while co-authored studies involve in-situ radiation dosimetry, LEO satellite instrumentation, and Lagrange Point mission planning. His publications are cited by researchers in magnetospheric physics, radiation monitoring, and heliophysics, reflecting a growing academic influence in these interconnected fields. His publication record showcases rigor, collaboration, and technical depth.

๐Ÿงช Research Skills

Jaeyoung possesses advanced research skills in data analysis, modeling, and scientific programming, with proficiency in tools like Geant4, IDL, and radiation models such as KREAM and NAIRAS. His work often integrates satellite observations with ground-based measurements, enabling high-accuracy wave propagation tracking and dose validation. He is trained in ionospheric predictions using GNSS and spaceborne sensors, and frequently participates in capacity-building workshops. His technical and analytical capabilities are grounded in real-world datasets, making his research both robust and application-driven, and positioning him as a multi-skilled astrophysicist.

๐Ÿ‘จโ€๐Ÿซ Teaching Experience

Jaeyoungโ€™s experience as a mathematics teacher for middle to high school students highlights his strong communication skills and ability to simplify complex concepts. He also delivered public talks on basic astronomy and space science to students at Gyeonggi Global School, reflecting a passion for outreach and education. His dual role as educator and researcher bridges academic theory and practical understanding, allowing him to mentor and inspire young science enthusiasts. His teaching background enhances his effectiveness in collaborative environments and positions him as a future leader in STEM education.

๐Ÿ† Awards and Honors

Jaeyoung has earned significant recognition, including the First Prize at the 2023 UST/KASI Young Researcher Workshop and the 2022 UST Proposal Challenge for his innovative work on KREAM-py development. He also received the Excellent Mentee Award at the 2021 UST Global Mentoring Conference. These awards reflect his dedication, originality, and teamwork in tackling complex space science challenges. His achievements not only highlight his technical expertise but also his ability to lead and inspire in academic and research communities.

๐Ÿš€ Legacy and Future Contributions

Jaeyoung aims to pioneer research in space weather prediction, radiation hazard mitigation, and magnetospheric dynamics. His interdisciplinary foundation and international collaborations equip him to lead global research initiatives in space science. As a committed educator and innovator, he is likely to influence the next generation of scientists and contribute to future space missions and safety systems. His ongoing efforts to integrate space radiation models with real-time observations will have lasting impacts on both science and public safety, ensuring his legacy as a visionary scientist and mentor.

Publications Top Notes

  • ๐Ÿ“ Comparison of storm and non-storm periods mid-latitude Pc1 pulsation characteristics โ€“ Kwak, J. et al. โ€“ Journal of Space Weather and Space Climate (2024)

  • ๐Ÿ“ก Initial Results of Low Earth Orbit Space Radiation Dosimeter on Board the Next Generation Small Satellite-2 โ€“ Nam, U., Kwak, J. et al. โ€“ Journal of Astronomy and Space Sciences (2024)

  • ๐ŸŒž Long-Term Science Goals with In Situ Observations at the Sun-Earth Lagrange Point L4 โ€“ Lee, D., Kwak, J. et al. โ€“ Journal of Astronomy and Space Sciences (2024)

  • ๐Ÿš€ Opening New Horizons with the L4 Mission: Vision and Plan โ€“ Cho, K., Kwak, J. et al. โ€“ Journal of the Korean Astronomical Society (2023)

  • โœˆ๏ธ Validation of KREAM based on in-situ measurement of aviation radiation in commercial flights โ€“ Hwang, J., Kwak, J. et al. โ€“ Journal of Astronomy and Space Sciences (2020)

 

 

Seyed Mohammad Ali Radmanesh | Interactions and fields | Best Researcher Award

Published on by High Energy Physics

Prof. Seyed Mohammad Ali Radmanesh | Interactions and fields | Best Researcher Award

Professor of Physics at University of New Orleans, United States

Dr. Seyed Mohammad Ali Radmanesh is a distinguished application scientist and experimental physicist with over 5 years of hands-on research experience in cryotronics, high-field magneto-transport measurements, and quantum materials. With a robust interdisciplinary background in materials science, applied physics, and engineering, Dr. Radmanesh has contributed to several high-impact studies, including publications in Nature-branded journals. He is recognized for his deep technical knowledge, data analysis capabilities, and experimental instrumentation expertise in low-temperature physics, making him a valuable contributor to cutting-edge material research.

๐Ÿ‘จโ€๐ŸŽ“Profile

Google scholar

Scopus

๐ŸŽ“ Early Academic Pursuits

Dr. Radmaneshโ€™s academic journey began with a B.Sc. in Materials Science and Engineering from Chamran University of Ahvaz, where he explored mechanical properties and heat treatment of metals. He deepened his expertise through an M.Sc. in Materials Science and Engineering at the University of Tehran, focusing on magnetic nanocomposites. His passion for condensed matter physics drove him to pursue an M.Sc. and Ph.D. in Applied Physics and Engineering at the University of New Orleans, where he became proficient in quantum materials research, developing strong foundations in low-temperature instrumentation and magneto-transport techniques.

๐Ÿงช Professional Endeavors

Professionally, Dr. Radmanesh has served as a researcher, application scientist, and visiting scholar at institutions like the National High Magnetic Field Laboratory (NHMFL). He led and collaborated on experiments investigating Dirac and Weyl semimetals, utilizing state-of-the-art systems such as Dilution Refrigerators, PPMS, SQUID, and VSM Cryostats. His role has involved device fabrication, data acquisition, and LabVIEW automation. He has also contributed to projects funded by NSF EPSCoR and has worked with various global experts on topics like topological superconductivity and London penetration depth, enhancing the experimental understanding of quantum electronic states.

๐Ÿ“š Contributions and Research Focus

Dr. Radmanesh’s research has focused extensively on quantum materials, particularly topological insulators, Dirac/Weyl semimetals, and unconventional superconductors. He has played a central role in uncovering nontrivial topological states, ฯ€ Berry phases, and electron coherence mechanisms under extreme cryogenic and magnetic conditions. His Ph.D. work on correlated materials and collaborative studies on half-Heusler compounds have significantly advanced the understanding of exotic superconducting states. Through his expertise in low-temperature transport measurements, Dr. Radmanesh continues to shape the landscape of experimental condensed matter physics with highly cited contributions.

๐ŸŒ Impact and Influence

Dr. Radmanesh’s work has had a global scientific impact, with publications in prestigious journals such as Nature Materials, Nature Communications, and Nature Physics. His findings on Dirac fermions, zero Landau levels, and spin-orbit coupling have informed theoretical and applied research in quantum computing, magnetoelectronics, and next-gen materials development. He has collaborated with leading research labs and scientists in the U.S. and internationally. His work continues to influence experimental techniques in cryotronics and quantum device engineering, while mentoring younger scientists and fostering interdisciplinary collaboration in academia and industry.

๐Ÿ“– Academic Citations

Dr. Radmanesh has authored or co-authored 11 peer-reviewed papers, with 5 published in Nature-branded journals and others in Physical Review B, Scientific Reports, and Journal of Magnetism and Magnetic Materials. His research has been cited in high-impact studies, reflecting the relevance and scientific rigor of his contributions. Particularly, papers on topological semimetals (SrMnSbโ‚‚, TaP) and superconductivity in half-Heuslers have received considerable academic attention. His 2020 article on nontrivial paired states remains an essential reference for researchers exploring novel quantum phases and low-dimensional superconductors.

๐Ÿ› ๏ธ Research Skills

Dr. Radmanesh possesses cutting-edge technical skills in cryogenic and magnetic instrumentation, including operation and troubleshooting of Dilution Refrigerators, PPMS, VSM, EPR, and LabVIEW-controlled systems. He is experienced in TDO-based London penetration depth measurements, Hall and resistivity measurements, and device prototyping using LPKF circuit board plotters. His command over data analysis tools (Origin, Maple, MATLAB) and software for experiment control has made him a reliable lead for complex experimental setups. He also applies vacuum systems and magnetic resonance tools to evaluate electronic, magnetic, and topological features in novel materials.

๐Ÿ‘จโ€๐Ÿซ Teaching Experienceย 

While his primary focus has been research, Dr. Radmanesh has supported academic environments through graduate-level mentoring, poster presentations, and technical workshops. He has helped undergraduate and master’s students with experimental setup, data interpretation, and instrument handling. During his time at the University of Tehran, he worked as a Computer Center expert, assisting peers with network systems and academic computing. Additionally, he has been an active presenter at APS and IEEE conferences, where he disseminated knowledge, discussed methodology, and contributed to collaborative learning, establishing himself as a knowledge facilitator in the scientific community.

๐Ÿ† Awards and Honors

Dr. Radmanesh has received multiple NSF EPSCoR Research Infrastructure Improvement (RII) Awards, recognizing his contribution to high-impact scientific projects. He has consistently earned top spots in poster competitions and has been inducted into Omicron Delta Kappa, the National Leadership Honor Society. A member of the IEEE and a reviewer for Materials Letters, he actively contributes to the scientific peer review process. These honors reflect his academic excellence, leadership, and professional integrity, distinguishing him as a prominent early-career researcher with a well-rounded scholarly and service profile.

๐ŸŒŸ Legacy and Future Contributions

Dr. Radmanesh is poised to become a leading innovator in quantum materials research and experimental cryogenic science. His future goals include developing next-generation instrumentation for quantum state detection, mentoring new researchers, and contributing to quantum device engineering applicable in computing and energy. His legacy will be built on combining deep theoretical insight with technical precision, advancing both academic understanding and practical application of novel materials. With plans to continue collaborative research and lead high-impact projects, Dr. Radmanesh is set to make lasting contributions that will shape the future of materials science and applied physics.

Publications Top Notes

Superconductivity in Layered Dichalcogenide Ptโ‚€.โ‚€โ‚‚TaSeโ‚‚ Single Crystals

  • Authors: S.M.A. Radmanesh, R. Ghanbari, A. Diaconu
    Journal: Solid State Communications
    Year: 2025

The Synthesis and Characterization of Hard-Soft Mnโ‚…โ‚‚Alโ‚„โ‚….โ‚‡Cโ‚‚.โ‚ƒโ€“ฮฑ-Fe Nanocomposite Magnets

  • Authors: S.N. Attyabi, S.M.A. Radmanesh, S.A.S. Ebrahimi, H. Dehghan
    Journal: Journal of Superconductivity and Novel Magnetism, Vol. 35 (5), pp. 1229โ€“1240
    Year: 2022

Stress-Induced Grain Refinement in Hard Magnetic Mnโ‚…โ‚‚Alโ‚„โ‚….โ‚‡Cโ‚‚.โ‚ƒ Fabricated Using the Ball-Milling Method

  • Authors: S.N. Attyabi, S.M.A. Radmanesh, S.A. Seyyed Ebrahimi, H. Dehghan, …
    Journal: Materials, Vol. 15 (22), Article 7919
    Year: 2022

Effect of the Heat Treatment on the Electrical Resistivity and Magnetization Reversal Behavior of MnAl Alloys

  • Authors: M. Shakouri, S.M.A. Radmanesh, S.A.S. Ebrahimi, H. Dehghan
    Journal: Materials Science and Engineering: B, Vol. 274, Article 115486
    Year: 2021

Nontrivial Paired States in Novel Topological Superconductors

  • Authors: S.M.A. Radmanesh, S.A.S. Ebrahimi, A. Diaconu, J.Y. Liu
    Journal: Journal of Alloys and Compounds, Vol. 848, Article 156498
    Year: 2020