Xuyang Liu | Hadron Physics | Research Excellence Award

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Mr. Xuyang Liu | Hadron Physics | Research Excellence Award

Associate Professor | Liaoning University | China

Mr. Xuyang Liu is an active researcher whose work is deeply rooted in hadron physics, contributing substantially to the global understanding of theoretical models and particle interactions within hadron physics. His research spans advanced investigations of baryon structure, multi-quark dynamics, meson cloud effects and form-factor behavior, all of which are central themes within hadron physics. Through high-quality publications, he has strengthened theoretical frameworks that support precision modeling in hadron physics and expanded collaborations with international groups working on perturbative chiral quark approaches and related computational methods. His scholarly contributions demonstrate methodological depth, consistently advancing the predictive capabilities of hadron physics while offering results that inform broader high-energy studies. His influence is reflected in his cumulative publication record, which showcases impactful findings recognized within the hadron physics community. By integrating refined analytical techniques and cross-disciplinary insights, he continually enhances the scientific dialogue surrounding hadron physics, contributing to both conceptual development and practical modeling applications. His sustained commitment to rigorous research has positioned him as a significant contributor to ongoing progress in hadron physics, supporting both theoretical advancement and societal scientific enrichment. Scopus profile of 306 Citations, 30 Documents, 10 h-index.

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Featured Publications

Prof. Dr. Kyosuke Ono | Standard Model Physics | Best Researcher Award

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Prof. Dr. Kyosuke Ono | Standard Model Physics | Best Researcher Award

Professor of Emeritus | Institute of Science Tokyo | Japan

Prof. Dr. Kyosuke Ono is an esteemed physicist renowned for his pioneering contributions to Standard Model Physics and applied tribology. His distinguished career at the Tokyo Institute of Technology, where he served as a professor and later as an emeritus scholar, is marked by extensive research in Standard Model Physics that bridges fundamental particle behavior with mechanical system dynamics. Throughout his tenure, Prof. Dr. Ono made significant advances in understanding sub-monolayer lubricant physics within the head-disk interface, offering crucial insights that align the precision of Standard Model Physics principles with nanoscale mechanical phenomena. His scholarly work reflects deep engagement with the continuum mechanics framework and its extension into sub-monolayer film theory, where Standard Model Physics served as the theoretical backbone guiding molecular interactions and force distributions at the atomic level. Prof. Dr. Ono’s prolific academic output includes numerous publications in leading international journals such as Tribology Letters, ASME Transactions on Tribology, and ASME Transactions on Applied Mechanics. His h-index of 26 demonstrates substantial influence and citation within the global Standard Model Physics and mechanical engineering communities. His collaborations with the Storage Research Consortium in Japan and industrial contributions as a technical advisor for hard disk drive development underscore his ability to translate Standard Model Physics insights into practical innovations with lasting industrial relevance. Furthermore, as an editorial board member for Lubricants (EDPI), he has consistently advanced the dissemination of high-quality research in the interdisciplinary field of tribology and Standard Model Physics. Through his remarkable integration of theory, experimentation, and application, Prof. Dr. Kyosuke Ono has significantly shaped modern interpretations of nanoscale lubrication and dynamics. His work stands as a testament to the versatility of Standard Model Physics in solving real-world engineering problems and continues to inspire the next generation of researchers to extend the boundaries of applied and theoretical physics.

Profile: ORCID

Featured Publication

1. Ono, K. (2016–2019). Analytical study of slider vibrations and lubricant flow in subnanometer head-disk interface [Grant No. 16K06039]. Ministry of Education, Science and Technology, Tokyo, Japan.

Xin-Jian Wen | QCD Diagram | Best Researcher Award

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Mr. Xin-Jian Wen | QCD Diagram | Best Researcher Award

Professor | Shanxi University | China

Mr. Xin-Jian Wen is a distinguished physicist renowned for his extensive contributions to Quantum Chromodynamics (QCD) and theoretical particle physics. His research is deeply rooted in exploring the properties of strongly interacting matter, the mechanisms underlying the QCD diagram transitions, and the behavior of strange quark matter in strong magnetic fields. Over the years, Mr. Xin-Jian Wen has built an influential academic profile through his pioneering studies on QCD diagram modeling, quark matter stability, and high-density nuclear matter, shaping global understanding in the field of QCD diagram phenomenology. His scholarly endeavors have led to numerous high-impact publications in leading journals such as Physical Review D, Physical Review C, and Journal of Physics G. Collaborating with eminent physicists from institutions including the University of Texas at El Paso and the Institute of High Energy Physics, he has advanced the precision of QCD diagram simulations and theoretical frameworks for quark-gluon interactions. His studies on the stability of strange quark matter and compact star structure through QCD diagram analyses have been particularly influential in connecting quantum field theory with astrophysical applications. Through sustained dedication, Mr. Xin-Jian Wen has become an integral contributor to theoretical high-energy physics, enriching the field of QCD diagram research and its broader implications in particle astrophysics. His approach integrates rigorous computational models with analytical perspectives, providing insights into QCD diagram transitions, nuclear phase structures, and the dynamics of matter under extreme conditions. His research continues to inspire advancements in QCD diagram studies, impacting both fundamental science and applied physics. With consistent academic productivity, strong collaborative networks, and impactful contributions to QCD diagram development, Mr. Xin-Jian Wen stands as a leading figure in experimental and theoretical high-energy studies. Scopus profile of 568 Citations, 44 Documents, 11 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Measuring the characterization of AFBR-S4N44P164M SiPM array at low temperatures for CEνNS detection. (2025). Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment.

2. Quark–hadron deconfinement at zero temperature in a strong magnetic field. (2025). European Physical Journal Plus.

3. Stability analysis of magnetized quark matter in Tsallis statistics. (2025). Universe.

4. Deconfinement of magnetized quark matter in a quasiparticle description. (2025). International Journal of Modern Physics A.

Prof. Dr. Evangelos N. Gazis | Experimental Particle Physics | Best Researcher Award

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Prof. Dr. Evangelos N. Gazis | Experimental Particle Physics | Best Researcher Award

Professor of Particle Physics | National Technical University of Athens | Greece

Prof. Dr. Evangelos N. Gazis, a distinguished scholar in Experimental Particle Physics, serves as a Professor at the National Technical University of Athens (NTUA) and holds guest professorships at CERN and Lund University. With a Scopus profile recording 4,942 citations, 108 documents, and an h-index of 24, his influence in the global Experimental Particle Physics community is profound. His extensive career integrates Experimental Particle Physics with nuclear, astro-particle, and accelerator physics, demonstrating a remarkable capacity for pioneering detector R&D, including gas detectors, micro-megas systems, and high-precision DAQ and control systems. Prof. Dr. Gazis has been instrumental in major CERN collaborations such as ATLAS, DELPHI, and CLIC, significantly contributing to the discovery of the Higgs boson and advancements in high-luminosity accelerator upgrades. His Experimental Particle Physics research extends into medical applications such as proton therapy and radioprotection, environmental and energy innovations, and cultural heritage preservation through nuclear technologies. As the Greek National Contact Physicist for multiple CERN collaborations and the Industrial Liaison Officer, he has fostered interdisciplinary partnerships between academia, industry, and government, demonstrating leadership in Experimental Particle Physics transfer and innovation. His contributions to education are equally remarkable, mentoring numerous students and promoting STEM engagement through ERASMUS+ initiatives that integrate Experimental Particle Physics into educational and technological frameworks. He has also authored monographs and co-authored over 1900 scientific papers, underscoring his lasting imprint on Experimental Particle Physics literature and global research dissemination. Prof. Dr. Gazis’s vision combines technical excellence with social and educational outreach, enhancing the societal relevance of Experimental Particle Physics across generations. His career stands as a benchmark of innovation, collaboration, and scientific integrity in Experimental Particle Physics, embodying professional excellence at an international level.

Profile: Scopus

Featured Publications

1. Simulation dosimetry studies for FLASH radiation therapy (RT) with ultra-high dose rate (UHDR) electron beam. (2024). Quantum Beam Science.

2. On the use of foam rubber for sealing applications. (2024). Tribology Letters.

3. Thermal diffusivity variation assessment on radio-frequency quadrupole Cu-OF copper due to proton irradiation. (2023). Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms.

4. The HEV ventilator: At the interface between particle physics and biomedical engineering. (2022). Royal Society Open Science.

5. Methods used for gas tightness test and percent oxygen monitoring of the NSW Micromegas detectors of LHC-ATLAS experiment. (n.d.). Conference Paper.