Dr. Sijo A K | Physics | Research Excellence Award

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Dr. Sijo A K | Physics | Research Excellence Award

Assistant Professor | Mary Matha Arts & Science College | India

Dr. Sijo A K is a dedicated academic and researcher affiliated with Mary Matha Arts and Science College Wayanad, contributing actively to interdisciplinary advancement across Physics, Materials Science, Science and Technology, Engineering, and Chemistry. His research profile reflects strong expertise in Physics with sustained contributions to experimental and theoretical Physics, applied Physics, and emerging Physics driven technologies. Through continuous engagement in Physics oriented investigations, he has demonstrated the ability to integrate Physics principles with materials innovation and engineering applications. His scholarly output highlights collaborative research culture, with interdisciplinary partnerships that strengthen Physics based problem solving and translational outcomes. The impact of his work in Physics extends to academic knowledge dissemination, mentoring, and societal relevance through technology enabled solutions grounded in Physics fundamentals. His research visibility and influence are supported by consistent citations and recognized scholarly contributions within the global Physics community. Scopus profile of 260 Citations, 29 Documents, 12 h index.

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Featured Publications


Optical and structural characterization of SILAR-coated Mn-doped ZnS films for LEDs

Journal of Materials Science-Materials in Electronics, 2025

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.

Citation Metrics (Scopus)

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277

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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

Citation Metrics (Google Scholar)

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                                  ■ Citations                       ■ h-index                       ■ i10-index

Featured Publications

Dr. Muhammad Asif | Optics | Young Scientist Award

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Dr. Muhammad Asif | Optics | Young Scientist Award

Postdoctoral Researcher | Shenzhen University | China

Dr. Muhammad Asif is a dedicated researcher with recognized expertise in the field of Optics, contributing actively to advancements in electromagnetic wave absorption and photonic device design. His work centers on computational modeling, simulation, and the development of next-generation Optics-based metamaterials, where a strong emphasis is placed on terahertz, infrared, and visible spectrum applications. With progressive contributions in Optics, he remains focused on enhancing absorber performance, improving device efficiency, and strengthening the scientific foundation of materials engineered for communication, sensing, and energy-harvesting technologies. The research record of Dr. Muhammad Asif reflects meaningful outcomes, including innovative ultra-wideband absorber structures that offer enhanced operational bandwidths, marking substantial relevance to modern Optics-driven industries and scientific frameworks. His publications demonstrate international visibility with multiple works featured in high-impact journals related to Optics, photonic materials, and terahertz absorbers, highlighting sustained productivity and scholarly depth. The collaborative efforts of Dr. Muhammad Asif extend globally across premier laboratories and institutions, reinforcing a dynamic research pipeline in applied Optics and computational photonics. He maintains active associations with advanced laboratories working in radio frequency integration, photonic information technologies, and Optics device engineering, where his contributions support technological growth, academic knowledge transfer, and cross-disciplinary innovation. His research outcomes underscore measurable scientific influence not only within theoretical Optics, but also in material engineering, metasurface development, and practical photonic implementation, thereby supporting the progression of sensing platforms, solar absorption systems, and terahertz technologies. This consistent engagement in Optics has positioned him among emerging scholars contributing significantly to the modern wave-interaction landscape through carefully engineered design strategies and simulation-based discoveries. Google Scholar profile of 76 Citations, 5 h-index, 2 i10-index.

Profile: Google Scholar

Featured Publications

1. Abdullah, M., Younis, M., Sohail, M. T., Wu, S., Zhang, X., Khan, K., Asif, M., & Yan, P. (2024). Recent progress of 2D materials‐based photodetectors from UV to THz waves: Principles, materials, and applications. Small, 20(47), 2402668.

2. Asif, M., Munir, R. M., & Wang, Q., Ouyang, Z. (2024). Graphene-based polarization insensitive structure of ultra-wideband terahertz wave absorber. Optical Materials, 154, 115759.

3. Asif, M., Ali, K., Munir, R. M., Anwar, S., Abdullah, M., Ouyang, Z., & Wang, Q. (2024). Ultra-wideband solar absorber via vertically structured GDPT metamaterials. Solar Energy, 282, 112957.

4. Asif, M., Wang, Q., Ouyang, Z., Lin, M., & Liang, Z. (2023). Ultra-wideband terahertz wave absorber using vertically structured IGIGIM metasurface. Crystals, 14(1), 22.

5. Abdullah, M., Younis, M., Sohail, M. T., Asif, M., Jinde, Y., Peiguang, Y., Junle, Q., ... (2025). Recent advancements in novel quantum 2D layered materials hybrid photodetectors from IR to THz: From principles to performance enhancement strategies. Chemical Engineering Journal, 504, 158917.

Dr. Ehsan Adibnia | Photonics | Best Researcher Award

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Dr. Ehsan Adibnia | Photonics | Best Researcher Award

Researcher | University of Sistan and Baluchestan | Iran

Dr. Ehsan Adibnia is a distinguished researcher in electrical engineering whose work exemplifies excellence in the integration of artificial intelligence and photonics. With a citation count of 6,447, an h-index of 45, and an i10-index of 153, his contributions to nanophotonics, plasmonics, and photonics-based optical communication have gained wide recognition. His research explores deep learning applications in photonic design, optical switching, and plasmonic structures, emphasizing the transformative role of photonics in next-generation computing and biosensing technologies. Dr. Adibnia has served as an assistant editor and reviewer for several high-impact journals, contributing to the advancement of global photonics research. His professional experience combines academic rigor and industrial insight, including expertise in programming, simulation tools like Lumerical and COMSOL, and PLC automation. His educational foundation in electrical engineering and his scholarly engagement at the University of Sistan and Baluchestan have provided a platform for innovative exploration in nanophotonics, quantum photonics, and integrated photonic circuits. Recognized for his excellence in photonics-driven design optimization, he has published influential studies on inverse design methods for fiber Bragg gratings, plasmonic resonators, and photonic crystal devices. His research interests span from artificial-intelligence-enhanced photonic structures to optical biosensors and metamaterials, underlining his commitment to interdisciplinary innovation. Through awards, editorial service, and sustained academic leadership, Dr. Adibnia continues to shape the evolving landscape of photonics, positioning his work at the intersection of computation, materials science, and optical engineering, where photonics defines the future of high-speed, intelligent systems.

Profiles: ORCID | Google Scholar

Featured Publications

1. Mirbagheri, M., Adib, E., Hughes, B. R., Waldman, S. D., Banquy, X., & Hwang, D. K. (2019). Advanced cell culture platforms: A growing quest for emulating natural tissues. Materials Horizons, 6(1), 45–71.

2. Esteki, M., Poorali, B., Adib, E., & Farzanehfard, H. (2015). Interleaved buck converter with continuous input current, extremely low output current ripple, low switching losses, and improved step-down conversion ratio. IEEE Transactions on Industrial Electronics, 62(8), 4769–4776.

3. Bahrami, H., Farhangi, S., Iman-Eini, H., & Adib, E. (2017). A new interleaved coupled-inductor nonisolated soft-switching bidirectional DC–DC converter with high voltage gain ratio. IEEE Transactions on Industrial Electronics, 65(7), 5529–5538.

4. Adib, E., & Farzanehfard, H. (2008). Family of zero-current transition PWM converters. IEEE Transactions on Industrial Electronics, 55(8), 3055–3063.

5. Adib, E., & Farzanehfard, H. (2009). Zero-voltage transition current-fed full-bridge PWM converter. IEEE Transactions on Power Electronics, 24(4), 1041–1047.*

Prof. Nikolai V. Gaponenko | Physics | Best Researcher Award

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Prof. Nikolai V. Gaponenko | Physics | Best Researcher Award

Professor | Belarusian State University of Informatics and Radioelectronics  | Belarus

Prof. Nikolai V. Gaponenko, a distinguished figure in physics, serves as Head of the Laboratory of Nanophotonics at the Belarusian State University of Informatics and Radioelectronics, where his extensive contributions to solid-state physics and nanophotonics have gained international recognition. His education in physics laid a robust foundation for pioneering research in optically anisotropic materials and sol-gel synthesis within the physics of photonic band gap structures. Throughout his professional experience, Prof. Gaponenko has led numerous interdisciplinary physics collaborations with global institutes, advancing luminescence technologies and nanostructure fabrication. His physics research encompasses photonic crystals, perovskite nanocomposites, and upconversion luminescence phenomena, with over a hundred high-impact publications and patents that redefine the role of physics in material design. Honored with several research distinctions, he has strengthened Belarus’s scientific presence through innovative physics-based solutions for electronic and photonic applications. His exceptional physics skills include experimental synthesis, spectroscopic analysis, and photonic modeling that bridge theory and engineering in nanophotonics. As an educator and physicist, he integrates practical and theoretical physics with creativity and leadership, inspiring scientific excellence. Prof. Nikolai V. Gaponenko’s career embodies the transformative potential of physics in shaping sustainable technological progress through deep insight, research integrity, and global collaboration.

Profiles: Google Scholar | ORCID

Featured Publications

1. Bogomolov, V. N., Gaponenko, S. V., Germanenko, I. N., Kapitonov, A. M., et al. (1997). Photonic band gap phenomenon and optical properties of artificial opals. Physical Review E, 55(6), 7619.

2. Dorofeev, A. M., Gaponenko, N. V., Bondarenko, V. P., Bachilo, E. E., Kazuchits, N. M., et al. (1995). Erbium luminescence in porous silicon doped from spin‐on films. Journal of Applied Physics, 77(6), 2679–2683.

3. Gaponenko, N. V., Davidson, J. A., Hamilton, B., Skeldon, P., Thompson, G. E., et al. (2000). Strongly enhanced Tb luminescence from titania xerogel solids mesoscopically confined in porous anodic alumina. Applied Physics Letters, 76(8), 1006–1008.

4. Lutich, A. A., Gaponenko, S. V., Gaponenko, N. V., Molchan, I. S., Sokol, V. A., et al. (2004). Anisotropic light scattering in nanoporous materials: A photon density of states effect. Nano Letters, 4(9), 1755–1758.

5. Gaponenko, N. V. (2001). Sol–gel derived films in meso-porous matrices: porous silicon, anodic aluminum and artificial opals. Synthetic Metals, 124(1), 125–130.

Dr. Kammogne Djoum Nana Anicet | Physics and Astronomy | Best Researcher Award

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Dr. Kammogne Djoum Nana Anicet | Physics and Astronomy | Best Researcher Award

Assistant Lecturer | African Institute of Mathematical Sciences | Cameroon

Dr. Kammogne Djoum Nana Anicet is a distinguished scholar in Physics and Astronomy whose academic and research journey reflects deep expertise in theoretical condensed matter physics. Having earned his Ph.D. with highest distinction from the University of Dschang, his work in Physics and Astronomy encompasses teaching, research, and numerous publications in top journals such as Physics Letters A and Chinese Journal of Physics. His professional experience includes roles as a teaching assistant at AIMS Cameroon and lecturer at the University of Dschang, where he taught electromagnetism, electrostatics, quantum physics, and solid-state physics—core pillars of Physics and Astronomy. Dr. Kammogne’s research explores quantum transitions, level-crossing phenomena, and spontaneous emission models, all vital areas in modern Physics and Astronomy. His outstanding performance has earned him multiple awards, including Best Researcher recognitions from ScienceFather, Scifat, and WorldTopScientists, along with a Presidential Award for Excellence. His skills in Mathematica, Python, LaTeX, and computational tools like Qutip enhance his research capabilities in Physics and Astronomy. With active participation in international conferences and collaborations, Dr. Kammogne continues to contribute innovative insights to the global Physics and Astronomy community. His dedication, technical proficiency, and analytical acumen define him as a leading researcher advancing frontiers in Physics and Astronomy, where his commitment to knowledge and excellence embodies the essence of scientific achievement and innovation in this dynamic field.

Profiles: Google Scholar | ORCID

Featured Publications

1. Kammogne, A. D., Kenmoe, M. B., & Fai, L. C. (2022). Statistics of interferograms in three-level systems. Physics Letters A, 425, 127872.

2. Kammogne, A. D., Issofa, N., & Fai, L. C. (2024). Non-resonant exponential Nikitin models with decay. Chinese Journal of Physics.

3. Kammogne, A. D., & Fai, L. C. (2025). Spontaneous emission in an exponential model. Chinese Journal of Physics.

4. Tchapda, A. B., Kenmoe, M. B., & Fai, L. C. (2017). Landau-Zener transitions in a qubit/qutrit periodically driven in both longitudinal and transverse directions. arXiv preprint arXiv:1708.04184.

5. Kammogne, A. D. (2025). Effect of spontaneous emission on a tanh model. Chinese Journal of Physics.