Assist. Prof. Dr. Dinesh Kumar Chaudhary | Physics | Research Excellence Award

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Assist. Prof. Dr. Dinesh Kumar Chaudhary | Physics | Research Excellence Award

Assistant Professor | Tribhuvan University | Nepal

Assist. Prof. Dr. Dinesh Kumar Chaudhary is an accomplished academic and researcher with strong expertise in Physics, actively contributing to experimental and applied Physics with emphasis on semiconductor Physics, materials Physics, sensor Physics, and nanostructured systems. His work in Physics integrates thin film Physics, gas sensing Physics, optical Physics, and electrical Physics, demonstrating consistent advancement of Physics driven solutions for real world applications. He has authored multiple peer reviewed publications in reputed journals, reflecting sustained impact in Physics research and interdisciplinary Physics collaboration with international scientists. His Physics contributions have supported advancements in sensing technologies, energy related Physics applications, and applied Physics methodologies relevant to industry and society. Through active collaboration, peer review service, and scholarly dissemination, he strengthens the global Physics community and promotes responsible Physics research aligned with societal needs. His academic service and research engagement highlight a commitment to high quality Physics education, innovation in Physics experimentation, and knowledge transfer through Physics based solutions that support technological and environmental progress. Scopus profile of 277 Citations, 24 Documents, 11 h index.

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Sensing Performance of a ZnO-based Ammonia Sensor

Journal of Physical Science, 2022
Cited by 40

Dr. Sergey Uchaikin | Quantum Sensors | Lifetime achievement Award

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Dr. Sergey Uchaikin | Quantum Sensors | Lifetime achievement Award

Senior Research Fellow | Institute for Basic Science | South Korea

Dr. Sergey Uchaikin is a globally recognized scientist and research leader with outstanding contributions to Quantum Sensors research, development, and large scale implementation. His expertise centers on Quantum Sensors for low temperature physics, superconducting technologies, precision measurement, and frontier particle physics experiments, where Quantum Sensors play a decisive role in sensitivity and reliability. He has authored more than one hundred peer reviewed publications that advance Quantum Sensors performance, noise reduction, and system integration, earning widespread citations across the international scientific community. His work on Quantum Sensors has enabled breakthroughs in axion dark matter searches, quantum limited amplification, and cryogenic detection platforms, directly impacting fundamental science and emerging quantum technologies. Through extensive collaborations with leading research institutes and industrial partners worldwide, he has translated Quantum Sensors innovations into practical systems for quantum computing, precision instrumentation, and advanced sensing applications. His leadership continues to shape global progress in Quantum Sensors research, fostering innovation, collaboration, and long term societal benefit in science and technology. Google Scholar profile of 6493 Citations, 28 h-index, 45 i10 index

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Featured Publications

Prof. Elvira Rossi | High Energy Physics | Research Excellence Award

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Prof. Elvira Rossi | High Energy Physics | Research Excellence Award

Associate Professor in Particle Physics | University of Naples Federico II | Italy

Prof. Elvira Rossi is a leading experimental scientist whose contributions have significantly advanced global High Energy Physics through pioneering research, interdisciplinary collaborations, and influential work within major international laboratories. Her research spans fundamental interactions, precision measurements, detector technologies, artificial intelligence applications, and large-scale data analysis, reinforcing the core pillars of modern High Energy Physics. She has played a major role in collaborations dedicated to High Energy Physics, including long-standing involvement in ATLAS and activities connected to future collider programs, where her work supports advancements in particle detection, trigger systems, calibration studies, and complex reconstruction strategies. Her scientific output reflects deep engagement with High Energy Physics, with impactful publications, extensive citation influence, and a strong presence across collaborative research networks. She has contributed to major discoveries, precision analyses, high-performance computing initiatives, and methodological innovations that benefit the broader High Energy Physics community and society through technological transfer, scientific outreach, and the development of advanced computational frameworks. Her sustained commitment to High Energy Physics, combined with her leadership roles and contributions to detector development and data-driven analysis, highlights her as a prominent figure shaping the future directions of High Energy Physics at the global level. Professional research metrics Scopus profile of 70403 Citations, 1211 Documents, 126 h-index.

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Featured Publications

Kai-Li Wang | Physics and Astronomy | Young Scientist Award

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Mr. Kai-Li Wang | Physics and Astronomy | Young Scientist Award

Postdoctoral Researcher | Soochow University | China

Mr. Kai-Li Wang is a leading researcher whose contributions in Physics and Astronomy have positioned him at the forefront of advanced semiconductor and perovskite device innovation. His work demonstrates a strong command of Physics and Astronomy, especially in areas related to organic and perovskite semiconductor mechanisms, device engineering, and photophysical behavior crucial to next-generation energy technologies. Across more than eighty publications, his research in Physics and Astronomy consistently advances fundamental understanding while delivering high-impact practical outcomes for photovoltaic and optoelectronic systems. His publications in major journals such as Science, JACS, Advanced Materials, Advanced Energy Materials, and Nano Letters reflect exceptional influence within global Physics and Astronomy communities. Mr. Kai-Li Wang’s expertise integrates material design, vacuum-based fabrication strategies, tandem and indoor photovoltaics, and defect passivation concepts technical areas rooted deeply in Physics and Astronomy. Through multidisciplinary collaborations bridging chemistry, nanotechnology, and device engineering, he elevates the role of Physics and Astronomy in solving large-scale energy and sustainability challenges. His work has reshaped modern understanding of perovskite crystallization, interface engineering, charge-transfer pathways, and stability mechanisms, making him a consistent contributor to international advancements in Physics and Astronomy. As a co-inventor on multiple patents and a frequent collaborator with highly cited research groups, Mr. Kai-Li Wang exemplifies the societal value of Physics and Astronomy through innovations aimed at high-efficiency, low-cost, and environmentally responsible energy conversion. His research continues to influence experimental design and industrial translation across the expanding global fields of photovoltaics, semiconductor materials, and applied Physics and Astronomy, reinforcing the discipline’s vital impact on technological progress. Google Scholar profile of 6389 Citations, 39 h-index, 94 i10-index.

Profiles: Google Scholar | ORCID

Featured Publications

1. Wang, R., Xue, J., Wang, K. L., Wang, Z. K., Luo, Y., Fenning, D., Xu, G., Nuryyeva, S., … (2019). Constructive molecular configurations for surface-defect passivation of perovskite photovoltaics. Science, 366(6472), 1509–1513.

2. Igbari, F., Wang, R., Wang, Z. K., Ma, X. J., Wang, Q., Wang, K. L., Zhang, Y., Liao, L. S., … (2019). Composition stoichiometry of Cs₂AgBiBr₆ films for highly efficient lead-free perovskite solar cells. Nano Letters, 19(3), 2066–2073.

3. Xue, J., Wang, R., Chen, X., Yao, C., Jin, X., Wang, K. L., Huang, W., Huang, T., … (2021). Reconfiguring the band-edge states of photovoltaic perovskites by conjugated organic cations. Science, 371(6529), 636–640.

4. Xue, J., Wang, R., Wang, K. L., Wang, Z. K., Yavuz, I., Wang, Y., Yang, Y., Gao, X., … (2019). Crystalline liquid-like behavior: surface-induced secondary grain growth of photovoltaic perovskite thin film. Journal of the American Chemical Society, 141(35), 13948–13953.

5. Phung, N., Félix, R., Meggiolaro, D., Al-Ashouri, A., Sousa e Silva, G., … (2020). The doping mechanism of halide perovskite unveiled by alkaline earth metals. Journal of the American Chemical Society, 142(5), 2364–2374.

Muhammad Mustafa Dastageer | Physics and Astronomy | Best Researcher Award

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Mr. Muhammad Mustafa Dastageer | Physics and Astronomy | Best Researcher Award

Research Assistant | University of Engineering and Technology | Pakistan

Mr. Muhammad Mustafa Dastageer is a dedicated researcher whose work is deeply rooted in the advancing frontiers of Physics and Astronomy. His scientific contributions focus on laser spectroscopy, plasma diagnostics, and machine-learning-assisted analytical techniques, forming a strong foundation for impactful research within the broader domains of Physics and Astronomy. Through his involvement in collaborative projects spanning national and international institutions, he has strengthened the integration of experimental methods with computational intelligence, demonstrating how Physics and Astronomy can bridge fundamental inquiry and applied innovation. Mr. Dastageer has contributed to significant publications addressing biomedical sensing, laser–matter interaction, and materials characterization, with his research appearing in reputable scientific journals. His role in major collaborative efforts, including studies on laser-induced breakdown spectroscopy for medical applications, underscores his commitment to expanding the practical relevance of Physics and Astronomy. His publications highlight rigorous experimental methodology, interdisciplinary coordination, and a clear dedication to scientific advancement. In addition to research excellence, he has actively contributed to scholarly events, conferences, and scientific communities, further reinforcing the global impact of Physics and Astronomy. His participation in academic symposiums and specialized workshops reflects his ongoing effort to promote knowledge exchange and foster innovation. Through these engagements, he contributes to shaping the evolving landscape of Physics and Astronomy, ensuring that theoretical understanding and technical application continue to progress side by side. With a professional trajectory centered on academic rigor, scientific integrity, and international collaboration, Mr. Dastageer remains committed to pushing forward the boundaries of Physics and Astronomy. His work exemplifies how modern research in Physics and Astronomy can meaningfully contribute to society, healthcare, materials science, and technological development. Scopus profile of 2 Citations, 3 Documents, 1 h-index.

Profiles: Google Scholar | ORCID | Scopus

Featured Publications

1. Mustafa, M., Latif, A., Jehangir, M., & Siraj, K. (2022). Nd: YAG laser irradiation consequences on calcium and magnesium in human dental tissues. Lasers in Dental Science, 6(2), 107–115.

2. Mustafa, M., Latif, A., & Jehangir, M. (2022). Laser-induced breakdown spectroscopy and microscopy study of human dental tissues. Electron Microscopy, 1–14.

3. Dastageer, M. M., Siraj, K., Pedarnig, J. D., Zhang, D., Qasim, M., Rahim, M. S. A., ... (2025). From fundamentals of laser-induced breakdown spectroscopy to recent advancements in cancer detection and calcified tissues analysis: An overview (2015–2025). Molecules, 30(21), 4176.

4. Mushtaq, S., Siraj, K., Rahim, M. S. A., Younas, Q., Hussain, B. M., Qasim, M., ... (2025). Analysis of edible silver foils under steady magnetic field by calibration free laser induced breakdown spectroscopy (CF-LIBS). Iranian Journal of Science, 49(3), 889–899.

5. Younas, Q., Siraj, K., Osipowicz, T., Naeem, S., Zhao, Y., Tan, C. C., Bashir, S., ... (2025). Impact of gold ions on nanohardness and various characteristics of G-metal alloy surface. Metals and Materials International, 1–17.

Mehabaw Fikrie Yehuala |  Computaional Physics | Best Researcher Award

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Mr. Mehabaw Fikrie Yehuala |  Computaional Physics | Best Researcher Award

Chief Academic Technical Assistant | University of Gondar | Ethiopia

Mr. Mehabaw Fikrie Yehuala is an emerging researcher and academic professional specializing in Computational Physics, with an active role as Chief Academic Technical Assistant at the University of Gondar. His career reflects a deep commitment to advancing Computational Physics through theoretical modeling, simulation techniques, and practical implementation in modern physical systems. His research expertise centers on Computational Physics applications in material dynamics, phase separation, and simulation-based investigations, particularly focusing on systems involving complex mixtures and energy interactions. Through his scholarly journey, Mr. Mehabaw has demonstrated a rigorous approach to Computational Physics, integrating programming proficiency in Python, Fortran, and LaTeX with analytical frameworks to model and interpret physical phenomena. His publication in Separation Science and Technology stands as a key contribution to the scientific community, highlighting the relevance of Computational Physics in studying the phase separation of oil–water mixtures using Monte Carlo simulation methods. His collaborative research embodies an interdisciplinary essence, bridging experimental insights with the predictive strength of Computational Physics. Mr. Mehabaw’s professional engagement extends beyond research into educational innovation, where he has contributed significantly to the development of physics laboratory manuals and academic resource materials, further strengthening the pedagogical aspects of Computational Physics education. His recognition for academic excellence and active participation in institutional development underscores his leadership and dedication to the advancement of scientific knowledge. As an analytical thinker and a collaborative scientist, Mr. Mehabaw continues to explore new dimensions in Computational Physics, contributing to both academic and societal progress. His vision emphasizes fostering research-driven learning environments and leveraging Computational Physics methodologies to address real-world scientific and industrial challenges, marking him as a promising contributor to the global physics and research community.

Profile: ORCID

Featured Publication

1. Fikrie, M., Birhanu, T., Bassie, Y., Abebe, Y., & Temare, Y. (2025). Investigation of phase separation of mixture of oil and water in Monte Carlo simulation. Separation Science and Technology.

Assist. Prof. Dr. Vladimir A. Pakhotin | Physics and Astronomy | Best Researcher Award

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Assist. Prof. Dr. Vladimir A. Pakhotin | Physics and Astronomy | Best Researcher Award

Senior Research Scientist | Ioffe Institute | Russia

Assist. Prof. Dr. Vladimir A. Pakhotin has made significant contributions to the interdisciplinary field of Physics and Astronomy, advancing research in electron emission and the electro-physical properties of polymers. His extensive background in Physics and Astronomy from the Saint-Petersburg State Polytechnic University and the Ioffe Institute laid the foundation for his innovative studies in the emission of charged particles and electrical breakdown phenomena. Throughout his professional journey as a Senior Researcher at the Strength Physics Laboratory, he has exemplified excellence in experimental Physics and Astronomy, merging theoretical insight with practical investigation. His research interest in Physics and Astronomy focuses on understanding the structural behavior of materials under varying electromagnetic conditions, contributing valuable data to polymer physics and electronic material design. Recognized for his prolific scholarly output, with over 150 publications, he stands as a respected figure in Physics and Astronomy. His awards and honors highlight his dedication to advancing material science and Physics and Astronomy innovation. His research skills encompass advanced instrumentation, emission analysis, and material characterization techniques that enhance discoveries in Physics and Astronomy. In conclusion, Assist. Prof. Dr. Vladimir A. Pakhotin’s lifelong pursuit of knowledge continues to inspire new generations of scientists, reinforcing the global impact of Physics and Astronomy research. His Scopus profile of 125 Citations, 28 Documents, 7 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Pakhotin, V. A., Semenov, S. E., & Sudar, N. T. (2025). Increasing the lifetime of polymer dielectrics in an AC field by using phosphorescent dopants: Theoretical justifications and numerical simulation. Journal of Applied Physics.

2. Pakhotin, V. A., & Semenov, S. E. (2024). Redistribution of electric field strength in insulation using electrets. IEEE Transactions on Dielectrics and Electrical Insulation.

3. Semenov, S. E., Sudar, N. T., & Pakhotin, V. A. (2024, October 17). Pulse electrical strength of polymer dielectric films. 2024 International Conference on Electrical Engineering and Photonics (EExPolytech).

4. Pakhotin, V. A., & Semenov, S. E. (2024, September 28). Charge stabilization in corona electrets made of HDPE film due to the formation of deep electron traps during its orientational stretching. Journal of Applied Physics.

5. Tipikin, A. A., Pakhotin, V. A., & Potapov, D. S. (2024, July 3). Technique for automatic profiling of underlying surface electric parameters on the very low frequencies radio path. Proceedings of Telecommunication Universities.

Prof. Heshmatollah Yavari | Quantum Science | Best Academic Researcher Award

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Prof. Heshmatollah Yavari | Quantum Science | Best Academic Researcher Award

Researcher at University of Isfahan, Iran

Prof. Heshmatollah Yavari has established himself as a leading figure in Quantum Science, contributing significantly to the understanding of superconductivity, superfluidity, and condensed matter systems. His work consistently integrates Quantum Science with theoretical models and practical applications. Prof. Yavari’s expertise in Quantum Science spans ultracold atomic gases, optical lattices, and neutron star physics, offering deep insights into strongly correlated systems. His pioneering role in Quantum Science research has positioned him among scholars who shape the evolution of modern physics. Prof. Yavari has consistently advanced Quantum Science through publications, collaborations, and innovative teaching. His vision within Quantum Science demonstrates a balance between theoretical foundations and cutting-edge applications, ensuring that Quantum Science remains central to future technological advances.

Professional Profile

ORCID Profile | Scopus Profile

Education 

Prof. Heshmatollah Yavari pursued his academic path with a clear dedication to Quantum Science, beginning with foundational studies in physics and advancing into specialized training in theoretical physics. His academic journey reflects a continuous engagement with Quantum Science, from undergraduate exploration to doctoral research. Prof. Yavari’s academic contributions reveal a strong commitment to Quantum Science, particularly in understanding transport phenomena, superconductors, and superfluids. Through each stage of education, Quantum Science remained the guiding principle of his learning and research. Prof. Yavari developed deep theoretical knowledge of Quantum Science, complemented by practical research projects that reinforced his scholarly standing. This trajectory highlights how Quantum Science shaped his intellectual development and prepared him for a lifetime of contribution to global scientific discovery.

Experience 

Prof. Heshmatollah Yavari’s professional career exemplifies dedication to Quantum Science, demonstrated through decades of teaching, mentoring, and research leadership. His role as professor of physics at the University of Isfahan highlights his continuous contribution to Quantum Science across multiple levels of academia. He has guided numerous students into advanced areas of Quantum Science, fostering innovation and critical thinking. His lectures on advanced quantum mechanics, statistical mechanics, and field theory exemplify the integration of Quantum Science with core theoretical frameworks. As a professional, Prof. Yavari actively collaborates with international scholars, expanding Quantum Science into interdisciplinary domains. His administrative roles and research coordination further underline his commitment to ensuring Quantum Science thrives as both a teaching discipline and a global research frontier.

Research Interest 

Prof. Heshmatollah Yavari’s research interests are firmly grounded in Quantum Science, with a focus on superconductivity, Bose-Einstein condensation, ultracold atomic gases, and topological insulators. His scholarly work connects Quantum Science with the mysteries of neutron stars, strongly correlated systems, and Majorana fermions. Prof. Yavari consistently expands the boundaries of Quantum Science by developing theories and models that address both fundamental and applied physics. Quantum Science drives his investigations into spin transport, optical lattices, and nonlocal effects in superconductors. His work reveals how Quantum Science contributes to understanding universal phenomena, from nanoscale materials to astrophysical systems. By integrating theory with experimental possibilities, Prof. Yavari demonstrates the transformative potential of Quantum Science across diverse scientific landscapes, ensuring it remains vital to modern physics.

Award and Honor

Prof. Heshmatollah Yavari has received recognition for his excellence in Quantum Science, reflecting his significant academic and research achievements. Awards and honors granted to Prof. Yavari underscore his enduring contributions to Quantum Science and theoretical physics. His published works in leading journals highlight the respect he commands in the Quantum Science community. Each accolade represents acknowledgment of his outstanding role in shaping Quantum Science and inspiring future generations of researchers. Honors received are not only a personal achievement but also evidence of his commitment to advancing Quantum Science globally. Through academic excellence and influential publications, Prof. Yavari’s reputation continues to strengthen, ensuring his name remains synonymous with quality and leadership in the growing field of Quantum Science.

Research Skill

Prof. Heshmatollah Yavari demonstrates advanced research skills in Quantum Science, applying both theoretical and computational methods to complex problems in physics. His expertise includes modeling superconductivity, analyzing transport properties, and interpreting Quantum Science phenomena in condensed matter systems. Prof. Yavari has mastered Quantum Science techniques related to ultracold atoms, superfluids, and nanoscale structures. His ability to integrate Quantum Science with interdisciplinary domains makes his skillset unique and impactful. Collaborations with other experts further amplify his Quantum Science research capabilities. His analytical approaches, problem-solving methods, and innovative thinking establish him as a skilled leader in Quantum Science. These research skills ensure that Prof. Yavari continuously contributes new insights and strengthens the foundation of Quantum Science in both academic and applied contexts.

Publication Top Notes 

Title: Purity of entangled photon pairs in a semiconductor–superconductor heterostructure in the presence of both Rashba and Dresselhaus SOCs
Authors: Zahra Saeedi; Heshmatollah Yavari
Journal: Materials Research Bulletin

Title: Effects of Rashba and Dresselhaus spin-orbit couplings on the critical temperature and paramagnetic limiting field of superconductors with broken inversion symmetry
Authors: H. Yavari; M. Tayebantayeba
Journal: Physica C: Superconductivity and its Applications

Title: Impurity and hybridization effects on the symmetry classification and magnetic response function of a two-band superconductor with interband pairing order
Authors: F Aghamohammadi Renani; H Yavari
Journal: Progress of Theoretical and Experimental Physics

Title: Three-body and Coulomb interactions in a quasi-two-dimensional dipolar Bose-condensed gas
Authors: Heshmatollah Yavari
Journal: Annals of Physics

Title: Effects of hybridization and spin–orbit coupling to induce odd-frequency pairing in two-band superconductors
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Shear viscosity in the strong interaction regime of a p-wave superfluid Fermi gas
Authors: Heshmatollah Yavari
Journal: Physics Letters A

Title: Anomalous viscosity of a chiral two-orbital superconductor in tight-binding model
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Progress in the development and construction of high temperature superconducting magnets
Authors: Heshmatollah Yavari
Journal: Superconductor Science and Technology

Title: On the Properties of Novel Superconductors
Authors: Heshmatollah Yavari
Journal: IntechOpen

Title: Effects of Thermally Induced Roton‐Like Excitation on the Superfluid Density of a Quasi‐2D Dipolar Bose Condensed Gas
Authors: Heshmatollah Yavari
Journal: Annalen der Physik

Title: Effect of long-range 1/r interaction on thermal and quantum depletion of a dipolar quasi-two-dimensional Bose gas
Authors: Heshmatollah Yavari
Journal: Low Temperature Physics

Title: Phase-dependent heat current of granular Josephson junction for different geometries
Authors: Heshmatollah Yavari
Journal: Physics Letters A

Title: Edge currents as a probe of the strongly spin-polarized topological noncentrosymmetric superconductors
Authors: Heshmatollah Yavari
Journal: Physical Review B

Title: Hall viscosity of a chiral two-orbital superconductor at finite temperatures
Authors: Heshmatollah Yavari
Journal: Physica C: Superconductivity and its Applications

Title: Temperature Dependence of the Thermal Conductivity of a Trapped Dipolar Bose-Condensed Gas
Authors: Heshmatollah Yavari
Journal: Brazilian Journal of Physics

Title: Low-Temperature Dependence of the Shear Viscosity in Superconductor S r 2 R u O 4
Authors: Heshmatollah Yavari
Journal: Journal of Superconductivity and Novel Magnetism

Title: Effect of nonlinearity, magnetic and nonmagnetic impurities, and spin-orbit scattering on the nonlocal microwave response of ad-wave superconductor
Authors: Heshmatollah Yavari
Journal: Low Temperature Physics

Title: Landau damping in a dipolar Bose–Fermi mixture in the Bose–Einstein condensation (BEC) limit
Authors: Heshmatollah Yavari
Journal: Chinese Physics B

Title: Depletion of the condensate in a dipolar Bose condensed gas in the presence of impurities
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Low temperatures shear viscosity of a two-component dipolar Fermi gas with unequal population
Authors: Heshmatollah Yavari
Journal: Annals of Physics

Conclusion

Prof. Heshmatollah Yavari’s career is a testament to the power of Quantum Science in shaping both knowledge and technology. His lifelong dedication to Quantum Science demonstrates how deep theoretical inquiry can lead to transformative discoveries. Prof. Yavari’s role as a professor, researcher, and author illustrates his enduring influence on Quantum Science. By nurturing students, publishing extensively, and advancing new ideas, he ensures that Quantum Science remains dynamic and progressive. His contributions prove that Quantum Science is not only central to academic inquiry but also critical for global innovation. In conclusion, Prof. Yavari embodies excellence in Quantum Science, representing a model scholar whose legacy will continue to inspire future advancements in the ever-expanding universe of Quantum Science.

Prof. Dr. Robert K. Nesbet | Physics | Lifetime achievement Award

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Prof. Dr. Robert K. Nesbet | Physics | Lifetime achievement Award

Prof. at IBM Almaden Research Cntr, United States

Prof. Dr. Robert K. Nesbet has made pioneering contributions to Physics, shaping the fields of computational Physics, atomic Physics, molecular Physics, theoretical Physics, solid-state Physics, astrophysics, and cosmology. His distinguished Physics research bridges both foundational and applied areas, advancing Physics through innovative theoretical methods and practical computational approaches. With Physics as the central theme of his career, Dr. Nesbet has enriched Physics literature through extensive publications in Physics journals and authored influential Physics books. His work in Physics continues to inspire researchers in Physics worldwide, highlighting the significance of Physics in solving fundamental problems. Physics remains at the core of his identity as a leader in Physics innovation, sustaining the progress of Physics across multiple disciplines and Physics domains.

Professional Profile

Scopus

Education 

Prof. Dr. Robert K. Nesbet education in Physics began at prestigious institutions where Physics formed the cornerstone of his academic journey. His BA in Physics and PhD in Physics established a strong foundation for exploring computational Physics, atomic Physics, molecular Physics, and cosmological Physics. At each stage, Physics guided his studies, fostering an enduring passion for advancing Physics knowledge. His immersive Physics education cultivated expertise in Physics methodologies, theories, and practical Physics applications. The rigorous Physics training he received empowered him to make transformative contributions to Physics scholarship. Through advanced Physics studies, he mastered the complexities of Physics, blending theoretical Physics insights with computational Physics tools to create impactful Physics research for global Physics communities.

Experience 

Prof. Dr. Robert K. Nesbet professional experience spans academia, industry, and research institutions, each deeply rooted in Physics. His Physics expertise has been applied to computational Physics, atomic Physics, and theoretical Physics roles at leading organizations. Positions in Physics-intensive environments allowed him to integrate Physics principles into real-world Physics problems, enhancing Physics knowledge across sectors. In both teaching Physics and conducting Physics research, he emphasized the interdisciplinary reach of Physics, collaborating with diverse Physics experts. His Physics career in institutions worldwide broadened the scope of Physics applications, from laboratory Physics investigations to astrophysical Physics modeling. Through each Physics role, Dr. Nesbet demonstrated the transformative potential of Physics in shaping scientific progress in Physics domains.

Research Interest 

Prof. Dr. Robert K. Nesbet research interests reflect the expansive nature of Physics, with a focus on computational Physics, atomic Physics, molecular Physics, solid-state Physics, astrophysical Physics, and cosmological Physics. His Physics work explores fundamental Physics problems, applying advanced Physics models to predict Physics phenomena. The integration of Physics theory and Physics computation in his projects bridges the gap between abstract Physics concepts and practical Physics applications. His Physics research addresses challenges in both microscopic Physics systems and large-scale Physics structures. The pursuit of new Physics knowledge drives his ongoing Physics investigations, inspiring future generations of Physics scholars to expand the frontiers of Physics with innovative Physics tools and collaborative Physics efforts.

Award and Honor

Prof. Dr. Robert K. Nesbet has been recognized for his substantial contributions to Physics with numerous Physics awards and Physics honors. These distinctions highlight his excellence in advancing Physics research and promoting Physics education. His leadership in Physics has earned international Physics acclaim, reflecting the profound impact of his Physics discoveries. The Physics community has acknowledged his innovative approaches to computational Physics, theoretical Physics, and astrophysical Physics. Such Physics awards serve as a testament to his enduring Physics influence, inspiring peers and students in Physics. Each Physics honor reinforces his status as a Physics authority whose commitment to Physics excellence strengthens the global Physics network and the advancement of Physics as a science.

Research Skill

Prof. Dr. Robert K. Nesbet possesses exceptional Physics research skills, encompassing computational Physics, analytical Physics, and theoretical Physics methodologies. His Physics skills enable him to model Physics systems, analyze Physics data, and solve complex Physics problems. Expertise in applying Physics theories to practical Physics scenarios defines his research approach. His mastery of Physics computation and simulation allows precise exploration of Physics interactions at various scales. Skilled in Physics-driven collaborations, he integrates cross-disciplinary Physics perspectives into cohesive Physics frameworks. These Physics skills not only produce high-quality Physics results but also foster innovation in Physics research. His technical Physics abilities are matched by his strategic Physics insight, advancing the collective understanding of Physics phenomena.

Publication Top Notes 

Title : Conformal gravity: Newton's constant is not universal
Citations: 0
Year: 2022

Title : Weyl Conformal Symmetry Model of the Dark Galactic Halo
Citations: 1
Year: 2022

Title : Implications of the Conformal Higgs Model
Citations: 0
Year: 2022

Title : Conformal Higgs model: Gauge fields can produce a 125 GeV resonance
Citations: 3
Year: 2021

Title : Conformal theory of gravitation and cosmology
Citations: 7
Year: 2022

Title : Dark energy density predicted and explained
Citations: 6
Year: 2019

Title : Theoretical implications of the galactic radial acceleration relation of McGaugh, Lelli, and Schombert
Citations: 8
Year: 2018

Title : Dark galactic halos without dark matter
Citations: 10
Year: 2015

Title : Conformal gravity: Dark matter and dark energy
Citations: 23

Conclusion

In conclusion, Prof. Dr. Robert K. Nesbet lifelong dedication to Physics has elevated multiple Physics disciplines, from computational Physics to cosmological Physics. His Physics journey demonstrates how one can merge Physics theory, Physics computation, and Physics application to advance human understanding of Physics. The breadth and depth of his Physics work have impacted Physics education, Physics research, and Physics practice globally. His Physics achievements exemplify the transformative power of Physics in addressing scientific challenges. As Physics continues to evolve, his contributions remain central to Physics progress. The Physics community recognizes him as a Physics pioneer whose Physics legacy will influence Physics exploration for generations in the realm of Physics.

Sergei Roshchupkin | Quantum Electrodynamics | Best Researcher Award

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Prof. Dr. Sergei Roshchupkin | Quantum Electrodynamics | Best Researcher Award

Professor of the Higher School of Fundamental Physical Research at Peter the Great St.Petersburg Polytechnic University (SPbPU), Russia

Sergei Pavlovich Roshchupkin, born on June 3, 1953, in Konotop, USSR, is a distinguished physicist specializing in quantum electrodynamics (QED) in strong electromagnetic fields. He earned his PhD in 1983 and Doctor of Sciences in 1995 from the National Research Nuclear University MEPhI. With decades of research and teaching experience, he has contributed significantly to theoretical physics, quantum optics, and laser-matter interactions. Currently a professor at Peter the Great St. Petersburg Polytechnic University, he has led numerous research projects and authored groundbreaking studies in high-energy physics. His work has earned him the title of Honored Scientist of Ukraine. 🏅📚

Professional Profile:

Orcid

Scopus

Google Scholar

Education & Experience 📖🔬

Education 🎓

  • 1971-1977 – Moscow Engineering Physics Institute (National Research Nuclear University MEPhI), Department of Experimental and Theoretical Physics

  • 1983 – PhD in Physics: “Bremsstrahlung of Electrons and Photoproduction of Electron-Positron Pairs in Strong Electromagnetic Fields”

  • 1995 – Doctor of Sciences (Phys & Maths): “Stimulated Emission and Spontaneous Bremsstrahlung in Relativistic Electron Collisions with Strong Light Fields”

Career & Employment 💼

  • 1977-1980 – Engineer at Russian Federal Nuclear Center (RFNC – VNIIEF) 🏗️

  • 1983-1992 – Research Assistant & Associate Professor at Sumy State University 🏫

  • 1992-2000 – Senior Staff Scientist & Professor at Institute of Applied Physics, NASU 🔬

  • 2000-2001 – Head of Department of Economic Cybernetics at Ukrainian Academy of Banking 🏦

  • 2001-2012 – Head of Laboratory of Quantum Electrodynamics, Institute of Applied Physics, NASU ⚛️

  • 2012-Present – Professor & Head of Quantum Electrodynamics of Strong Fields, Peter the Great St. Petersburg Polytechnic University 🏛️

Professional Development 📚✨

Sergei Pavlovich Roshchupkin has spent over four decades advancing research in quantum electrodynamics (QED) in strong electromagnetic fields. His studies focus on the interactions of intense laser radiation with electrons, ions, and cosmic phenomena like pulsars and magnetars. 🌌⚡ His pioneering work in nonlinear quantum optics and laser amplification in QED processes has shaped modern theoretical physics. With extensive teaching experience, he has mentored students in classical mechanics, electrodynamics, and quantum theory. His leadership in scientific departments and research labs has propelled international collaborations and groundbreaking discoveries in high-energy physics. 🚀📖

Research Focus 🔍🧪

Sergei Pavlovich Roshchupkin’s research is at the frontier of high-energy quantum electrodynamics (QED) and nonlinear quantum optics. He investigates strong electromagnetic fields and their influence on particle interactions, particularly in extreme astrophysical environments like pulsars and magnetars. 🌠⚡ His studies delve into laser-lepton and laser-ion interactions, uncovering new ways to amplify laser radiation using QED processes in strong fields. 💡 His work contributes to the understanding of fundamental physics laws governing particle behavior under ultra-intense conditions, crucial for advancements in plasma physics, astrophysics, and next-generation laser technology. 🔬💥

Awards & Honors 🏆🎖️

🏅 Honored Scientist of Ukraine – Awarded in May 2011 for outstanding contributions to physics and quantum electrodynamics.
📜 Full Professor Title – Awarded in 1997 at Sumy State University for excellence in research and teaching.
🎓 Doctor of Sciences (Phys & Maths) – Earned in 1995 for groundbreaking work in stimulated emission and electron bremsstrahlung in strong light fields.
🔬 Leader of Multiple Research Projects – Recognized internationally for contributions to high-energy physics and QED.

Publication Top Notes

  1. Quantum Entanglement of the Final Particles in the Resonant Trident Pair Production Process in a Strong Electromagnetic Wave

    • Journal: Photonics

    • Published: March 27, 2025

    • DOI: 10.3390/photonics12040307

    • Focus: This paper investigates quantum entanglement in the final particles produced during the resonant trident pair production process, which occurs under the influence of a strong electromagnetic wave. The study explores how entanglement manifests in this high-energy particle interaction.

  2. Generation of Narrow Beams of Super High-Energy Gamma Quanta in the Resonant Compton Effect in the Field of a Strong X-ray Wave

    • Journal: Photonics

    • Published: June 26, 2024

    • DOI: 10.3390/photonics11070597

    • Focus: This paper discusses the generation of narrow beams of super high-energy gamma quanta using the resonant Compton effect, particularly in the field of a strong X-ray electromagnetic wave. It focuses on how intense electromagnetic fields can influence the generation of these high-energy photons.

  3. The Generation of High-Energy Electron–Positron Pairs during the Breit–Wheeler Resonant Process in a Strong Field of an X-ray Electromagnetic Wave

    • Journal: Symmetry

    • Published: October 10, 2023

    • DOI: 10.3390/sym15101901

    • Focus: This article explores the generation of high-energy electron–positron pairs in the Breit–Wheeler resonant process under the influence of a strong X-ray electromagnetic field. It examines the conditions necessary for this process and its implications in quantum electrodynamics.

  4. Резонансный процесс Брейта-Уиллера в сильном электромагнитном поле

    • Journal: Теоретическая и математическая физика (Theoretical and Mathematical Physics)

    • Published: September 2023

    • DOI: 10.4213/tmf10449

    • Focus: This paper, in Russian, focuses on the Breit–Wheeler resonant process in strong electromagnetic fields. It analyzes the theoretical aspects of this phenomenon and its importance in high-energy physics.

  5. Generation of Narrow Beams of Ultrarelativistic Positrons (Electrons) in the Breit–Wheeler Resonant Process Modified by the Field of a Strong Electromagnetic Wave

    • Journal: Photonics

    • Published: August 18, 2023

    • DOI: 10.3390/photonics10080949

    • Focus: This paper discusses the modification of the Breit–Wheeler resonant process by a strong electromagnetic field, specifically focusing on the generation of narrow beams of ultrarelativistic positrons and electrons. The study explores how strong fields can influence particle acceleration and beam formation.

Conclusion

Professor Roshchupkin’s exceptional contributions to quantum electrodynamics, his leadership in theoretical physics research, and his recognition as an honored scientist make him a strong candidate for the Best Researcher Award. His work continues to shape modern physics, particularly in the fields of strong-field QED, non-linear optics, and astrophysical plasmas. His legacy in both research and academia is a testament to his excellence and impact on the global scientific community.