Dr. Christopher Mayero | Breakthrough Research Award

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Dr. Christopher Mayero | Breakthrough Research Award

Tom Mboya University | Kenya

Christopher Mayero is a Tutorial Fellow in Physics at Tom Mboya University, Homabay, Kenya, whose research centers on quantum optics, quantum information, and light–matter interaction dynamics. His scholarly contributions explore the Jaynes–Cummings and anti-Jaynes–Cummings (AJC) models, focusing on photon statistics, Rabi oscillations, atomic population inversion, and entanglement behavior in non-classical systems. Mayero has published five peer-reviewed papers indexed in Scopus, accumulating five citations and an h-index of 1, with several additional preprints addressing advanced topics in quantum coherence, squeezed light, and quantum teleportation. His work, featured in Quantum Information Processing and other international journals, provides theoretical insights applicable to quantum computing and quantum communication. A collaborator with scholars such as Joseph Akeyo Omolo and Stephen Onyango Okeyo, Mayero’s research aims to deepen the understanding of quantum field–atom interactions and contribute to Africa’s growing quantum science community. Through his commitment to teaching and research excellence, he continues to inspire emerging physicists and expand the frontier of theoretical quantum technologies.

Profiles : ScopusOrcid | Google Scholar

Featured Publications

Mayero, C., & Omolo, J. A. (2025). Superposition of red- and blue-sideband processes in interacting qubits: Effects of residual detuning. Quantum Information Processing, 24(10), 315.

Mayero, C. (2025). Atomic non-classicality: A study of the anti-Jaynes–Cummings interaction. Quantum Information Processing, 24(8), 259.

Mayero, C., & Omolo, J. A. (2024). Anti-Jaynes–Cummings interaction of a two-level atom with squeezed light: Photon statistics, atomic population inversion, and entropy of entanglement. Quantum Information Processing, 23(5), 182. https://doi.org/10.1007/s11128-024-04390-1

Mayero, C., & Omolo, J. A. (2024). Exploring Rabi oscillations, maximally entangled states, and perfect teleportation in the anti-Jaynes–Cummings interaction: Insights into quantum dynamics and entanglement applications. In Current Research Progress in Physical Science (Vol. 4). BP International. https://doi.org/10.9734/bpi/crpps/v4/2566

Mayero, C. (2023). Photon statistics and quantum field entropy in the anti-Jaynes–Cummings model: A comparison with the Jaynes–Cummings interaction. Quantum Information Processing, 22(5), 412. https://doi.org/10.1007/s11128-023-03912-7

Dr. Xiansheng Tang | Young Researcher Award

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Dr. Xiansheng Tang | Young Researcher Award

Laser Institute, Qilu University of Technology (Shandong Academy of Sciences) | China

Xiansheng Tang is an assistant researcher with a Ph.D., serving as a master’s degree supervisor and recognised as a key scientific researcher of the Shandong Province International Top Scientist Studio as well as a candidate academic leader in the field of optoelectronic semiconductor devices at the Laser Institute. He has presided over a youth project of the Provincial Natural Science Fund, a major basic research project in Shandong Province, and taken part in a key R&D plan of the Ministry of Science and Technology, a major innovation project in Shandong Province, and the “Jinan University 20-Item Project”. Tang’s research focuses on the preparation of optoelectronic semiconductor materials and devices, and he has published more than 20 SCI papers, of which 12 were as first author or corresponding author, and participated in the filing of more than 30 invention patents, of which 16 have been authorised. His recent works include studies on quantum confinement of photo-generated carriers in quantum wells (IEEE Photonics Journal, 2023) and improving solar-cell performance under non-perpendicular incidence by photonic crystals (IEEE Photonics Journal, 2021) as well as stripping GaN/InGaN epitaxial films and fabricating vertical GaN-based LEDs (Vacuum, 2021). According to publicly available profile information his publications tally over 20 (ResearchGate lists ~24) with citations in the low thousands. While the exact h-index is not clearly reported in a reliable database, his citation metrics suggest emerging influence in the field of semiconductor optoelectronics. His current appointment and project leadership indicate strong institutional recognition, and his work contributes to advancing high-performance optoelectronic device technologies, with implications for LEDs, solar cells, and III-V semiconductors. Tang continues to drive innovation in semiconductor materials and device architectures, positioning him as an up-and-coming scholar in optoelectronic semiconductor research.

Profile: Orcid 

Featured Publications

 Ding, D., Liu, W., Guo, J., Tan, X., Zhang, W., Han, L., Wang, Z., Gong, W., & Tang, X. (2023). Study on the quantum confinement of photo-generated carriers in quantum wells. IEEE Photonics Journal, 15(3), 1–8. https://doi.org/10.1109/JPHOT.2023.3269082

 Tang, X., Ma, Z., Wang, W., Deng, Z., Jiang, Y., Wang, W., Chen, H., Zhang, N., Huang, K., Du, C., et al. (2021). Improving the performance of solar cells under non-perpendicular incidence by photonic crystal. IEEE Photonics Journal, 13(4), 1–8. https://doi.org/10.1109/JPHOT.2021.3097070

 Tang, X., Ma, Z., Han, L., Deng, Z., Jiang, Y., Wang, W., Chen, H., Du, C., & Jia, H. (2021). Stripping GaN/InGaN epitaxial films and fabricating vertical GaN-based light-emitting diodes. Vacuum, 189, 110160. https://doi.org/10.1016/j.vacuum.2021.110160

Dr. Yuan Li | Environmental Physics | Interdisciplinary Physics Award

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Dr. Yuan Li | Environmental Physics | Interdisciplinary Physics Award

Dr. Yuan Li | X-Here Trek Laboratory (Establishing) | United States

Dr. Yuan Li is an innovative research scientist whose interdisciplinary work integrates cryospheric science, ice physics, and renewable energy engineering. He is internationally recognized for pioneering the concept of ice-based hydrogen energy, developing a self-sustaining solid-state proton extraction cycle that enables hydrogen production directly from ice without the need for electrodes or electrolytes. His research explores the microstructural behavior of ice and firn, advancing understanding of hydrogen migration and storage within frozen matrices. By combining cryogenic materials science, climate adaptation engineering, and polar glaciology, he bridges fundamental research with practical solutions for sustainable energy and environmental resilience. His publications in high-impact journals such as Sustainable Energy Technologies and Assessments, International Journal of Hydrogen Energy, and Nature Communications reflect the global significance of his work. Dr. Li’s “Ice to Hydrogen” innovation presents a transformative approach for decentralized, low-cost hydrogen production in remote and extreme environments. His contributions to cryogenic material characterization, freeze–thaw energy conversion, and ice-mediated desalination establish new directions for renewable energy systems. He utilizes advanced imaging techniques like X-ray micro-CT and cryo-SEM to study ice microstructures with unprecedented precision. His interdisciplinary expertise spans physics, materials science, and environmental sustainability. Through invited talks at global conferences, he has influenced the scientific dialogue on ice as a renewable resource. His work embodies the fusion of physical science and engineering innovation. Dr. Yuan Li continues to shape the emerging frontier of cryogenic energy technology, promoting a sustainable hydrogen future grounded in the physics of ice.

Profiles : Scopus |  Orcid 

Featured Publications

Li, H.-Y., & Li, Y. (2025, November). Ice to hydrogen: A self-sustaining cycle for decentralized green energy. Sustainable Energy Technologies and Assessments, 83, 104647.

Li, Y., Fu, C., & Li, H.-Y. (2025, September 13). Lessons from nature’s freeze crystallization—Perennial sea ice as a model for efficient salt rejection in desalination. Crystal Growth & Design.

Li, Y. (2025, June 24). Comments on linear-viscous flow of temperate ice [Preprint]. ESSOAr.

Li, Y. (2025, January). Hydrogen production via imperfective ice Ih. International Journal of Hydrogen Energy, 100, 727–735.

Li, Y., & Fu, C. (2024, December). Hydrogen storage—Learning from nature: The air clathrate hydrate in polar ice sheets. Sustainable Energy Technologies and Assessments, 72, 104007.

Li, Y. (2024, September). The improvement of hydrogen storage capacity via bubbles nucleated in ice-like nanotubes. Materials Today Sustainability, 27, 100856.

Prof. Jürg Fröhlich | Best Researcher Award

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Prof. Jürg Fröhlich | Best Researcher Award

ETH Zürich | Switzerland

Jürg (Martin) Fröhlich is Professor Emeritus of Theoretical Physics at ETH Zurich, renowned for his foundational contributions to mathematical physics, quantum field theory, and statistical mechanics. He earned his Diploma (1969) and Ph.D. (1972, with honors) in Theoretical Physics from ETH Zurich under Professor Klaus Hepp, focusing on the infrared problem in nonrelativistic quantum field models. Following his doctoral studies, he held academic positions at the University of Geneva, Harvard University, Princeton University, and the Institut des Hautes Études Scientifiques (IHES), before joining ETH Zurich in 1982, where he later helped establish the Pauli Center for Theoretical Studies. His research has profoundly influenced the understanding of phase transitions, localization phenomena, gauge theories, and topological phases of matter. Professor Fröhlich has published over 400 scientific papers, with more than 31,000 citations and an h-index of 91. He has received numerous prestigious honors, including the National Latsis Prize, the Dannie Heineman Prize for Mathematical Physics, the Marcel Benoist Prize, the Max Planck Medal, and the Henri Poincaré Prize. He is a Fellow of the American Mathematical Society, a member of the Academia Europaea, and an International Member of the U.S. National Academy of Sciences, reflecting his lasting influence on mathematical and theoretical physics.

Profiles : Google Scholar | Orcid 

Featured Publications

Fröhlich, J., & Spencer, T. (1983). Absence of diffusion in the Anderson tight-binding model for large disorder or low energy. Communications in Mathematical Physics, 88(2), 151–184.

Ambjørn, J., Durhuus, B., & Fröhlich, J. (1985). Diseases of triangulated random surface models, and possible cures. Nuclear Physics B, 257, 433–449.

Fröhlich, J., Simon, B., & Spencer, T. (1976). Infrared bounds, phase transitions and continuous symmetry breaking. Communications in Mathematical Physics, 50(1), 79–95.

Fröhlich, J., & Spencer, T. (1981). The Kosterlitz–Thouless transition in two-dimensional abelian spin systems and the Coulomb gas. Communications in Mathematical Physics, 81(4), 527–602.

Fröhlich, J. (1982). On the triviality of λϕ⁴ theories and the approach to the critical point in d > 4 dimensions. Nuclear Physics B, 200(2), 281–296.

Fernández, R., Fröhlich, J., & Sokal, A. D. (2013). Random walks, critical phenomena, and triviality in quantum field theory. Springer Science & Business Media.

Prof. Afzal S. M. | Best Researcher Award

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Prof. Afzal S. M. | Best Researcher Award

Physics Department, Aligarh Muslim University | India

Prof. S. M. Afzal is a Professor of Physics at Aligarh Muslim University, India, with over 25 years of experience in teaching and research. He obtained his Ph.D. in Physics from Aligarh Muslim University in 1997, specializing in atomic and laser spectroscopy. His research focuses on high-resolution spectroscopy, nonlinear optics, photonic materials, and optoelectronic applications. Prof. Afzal has made significant contributions to the development of experimental facilities and has conducted extensive studies on light–matter interactions using advanced laser and optical techniques. He has published more than 54 research papers in reputed international journals, achieving over 542 citations, an h-index of 12, and an i10-index of 17, reflecting the strong impact of his scholarly work. In addition, he has successfully completed five funded research projects and guided more than twenty postgraduate theses. His work integrates experimental and computational approaches for exploring nonlinear optical properties of organic and inorganic systems, contributing to advancements in photonics and laser technology. Through his dedicated research and mentorship, Prof. Afzal continues to play a vital role in advancing modern optical physics and inspiring the next generation of scientists.

Profiles : Research GateGoogle Scholar

Featured Publications

El-Shishtawy, R. M., Al-Zahrani, F. A. M., Afzal, S. M., Razvi, M. A. N., & Al-amshany, Z. M. (2016). Synthesis, linear and nonlinear optical properties of a new dimethine cyanine dye derived from phenothiazine. RSC Advances, 6(94), 91546–91556.

Kamaal, S., Mehkoom, M., Ali, A., Afzal, S. M., Alam, M. J., Ahmad, S., & Ahmad, M. (2021). Potential third-order nonlinear optical response facilitated by intramolecular charge transfer in a simple Schiff base molecule: Experimental and theoretical exploration. ACS Omega, 6(9), 6185–6194.*

Khan, S. A., Razvi, M. A. N., Bakry, A. H., Afzal, S. M., Asiri, A. M., & El-Daly, S. A. (2015). Microwave assisted synthesis, spectroscopic studies and nonlinear optical properties of bis-chromophores. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 137, 685–692.*

Fatima, A., Ali, A., Shabbir, S., Khan, M., Mehkoom, M., Afzal, S. M., Ahmad, M., & Ahmad, S. (2022). Synthesis, crystal structure, characterization, Hirshfeld analysis, molecular docking and DFT calculations of 5-phenylamino-isophthalic acid: A good NLO material. Journal of Molecular Structure, 132791.

Mehkoom, M., Afzal, S. M., Ahmad, S., & Khan, S. A. (2021). Physicochemical and nonlinear optical properties of novel environmentally benign heterocyclic azomethine dyes: Experimental and theoretical studies. PLOS ONE, 11(9), e0161613.*

Assist. Prof. Dr. Fikadu Geldasa | Best Researcher Award

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Assist. Prof. Dr. Fikadu Geldasa | Best Researcher Award

Walter Sisulu University | South Africa

Dr. Fikadu Takele Geldasa is an Assistant Professor of Physics at Walter Sisulu University, South Africa, and Oda Bultum University, Ethiopia. He has published 19 Scopus-indexed research papers, received more than 323 citations, and holds an h-index of 6. He obtained his Ph.D. in Materials Physics from Adama Science and Technology University. His research focuses on experimental and computational studies of functional nanomaterials using density functional theory (DFT) and materials characterization techniques. Dr. Geldasa works on the structural, electronic, and optical properties of doped metal oxides, perovskites, and semiconductor materials for applications in photocatalysis, energy conversion, and environmental remediation. His recent works on doped TiO₂ and α-NiS nanostructures provide insights into bandgap engineering and defect tuning for enhanced visible-light photocatalytic activity. He has published his research in leading journals such as Scientific Reports, Nanomaterials, Materials, and Physica Scripta. His interdisciplinary research integrates theory and experiment to develop advanced materials for renewable energy and sustainable technology. Through his scientific contributions, Dr. Geldasa is establishing himself as a promising researcher in materials physics and computational materials science, contributing significantly to the progress of clean energy and environmental technologies.

Profiles : ScopusOrcid | Research GateGoogle Scholar

Featured Publications

Geldasa, F. T., Dejene, F. B., Kebede, M. A., Hone, F. G., & Jira, E. T. (2025). Density functional theory study of chlorine, fluorine, nitrogen, and sulfur doped rutile TiO₂ for photocatalytic application. Scientific Reports, 15(1), 3390. https://doi.org/10.1038/s41598-024-84316-0

Geldasa, F. T., & Dejene, F. B. (2025). Transition metal doping effects on the structural, mechanical, electronic, and optical properties of α-NiS for photocatalysis applications via DFT + U insights. Applied Physics A. https://doi.org/10.1007/s00339-025-08942-9

Geldasa, F. T., & Dejene, F. B. (2025). First principles investigation of niobium and carbon-doped titanium dioxide for enhanced visible light photocatalytic activity. ChemistrySelect. https://doi.org/10.1002/slct.202504529

Geldasa, F. T., & Dejene, F. B. (2025). Exploration of vanadium and rhenium co-doped TiO₂ for enhanced photocatalytic performance via first principle density functional theory investigation. Physica Scripta. https://doi.org/10.1088/1402-4896/adf156

Geldasa, F. T., & Dejene, F. B. (2025). Density functional theory based exploration of structural, electronic, mechanical, thermodynamic, and optical properties of α-NiS for CO₂ adsorption. Journal of Physics: Condensed Matter. https://doi.org/10.1088/1361-648X/aded5f

Prof. Shuo Yang | Innovative Research Award

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Prof. Shuo Yang | Innovative Research Award

Shenyang Institute of Engineering | China

Prof. Shuo Yang is a distinguished researcher and Project Manager at the Shenyang Institute of Engineering, where he also serves as Managing Director of the Key Laboratory of Liaoning Province for Clean Combustion Power Generation and Heat-Supply Technology. He holds a Doctor of Engineering degree in Engineering Thermophysics from Northeastern University (2017), following his Master’s and Bachelor’s degrees in Thermal Engineering and Thermal Energy & Power Engineering from Liaoning Technical University. Dr. Yang has published 35 scientific papers, accumulating over 1,662 reads, 150 citations, and an h-index of 9 (as of 2025). His research focuses on microfluidics, thermocapillary and Marangoni convection, mesoscale fluid control, and clean combustion technologies. He integrates numerical simulations and experimental analyses to study complex interfacial and capillary phenomena, advancing understanding in energy and fluid mechanics. A recognized reviewer for leading journals such as Journal of Crystal Growth, Applied Sciences, and Symmetry, Dr. Yang also serves as a communication review expert for the National Natural Science Foundation of China. He has been honored with the prestigious “Ten Thousand Level” Talent Title under the Liaoning Province Hundred, Thousand and Ten Thousand Talent Project. His ongoing work continues to bridge theoretical and applied research in energy and fluid systems innovation.

Profiles : Research Gate | Orcid

Featured Publications

Xiao, Y., Cui, J., Pan, H., Zhu, L., Xu, B., Yang, X., Zhao, H., Yang, S., Zhao, Y., & Wirsum, M. (2025). Investigation of ammonia–coal co-combustion performance and NOx formation mechanisms under varied ammonia injection strategies. Energies, 18(21), 5609. https://doi.org/10.3390/en18215609

 Yang, S., Luo, J., Gao, Y., Wang, S., Zhang, Y., Wang, Y., Ge, P., Li, W., Zheng, Y., & Cui, J. (2024). Experimental study on the effects of washing time, washing temperature, and particle size on the combustion and ash formation characteristics of rice husk. ACS Omega, 9(52), 38820–38833. https://doi.org/10.1021/acsomega.4c08820

 Yang, S., Ge, P., Gao, Y., Luo, J., Wang, T., Liu, Z., Zheng, Y., Li, W., & Cui, J. (2024). Effect of a uniform axial magnetic field on the spatiotemporal evolution of thermocapillary convection in a high Prandtl fluid under microgravity. Symmetry, 16(12), 1645. https://doi.org/10.3390/sym16121645

 Xiao, W., Cui, J., Pan, H., Zhao, H., Yang, S., Xue, Z., Fu, Y., & Xu, Y. (2024). A study on the influence of oxy-hydrogen gas flame on the combustion stability of coal powder and nitrogen oxide emissions. Processes, 12(8), 1777. https://doi.org/10.3390/pr12081777

 Cui, J., Zhao, H., Xu, Y., Yang, S., Pan, H., Xiao, W., Fu, Y., & Xue, Z. (2024). Experimental investigation on oxy-hydrogen gas flame injecting coal powder gasification and combustion. Processes, 12(4), 692. https://doi.org/10.3390/pr12040692

Mr. Debasis Sahu | Best Researcher Award

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Mr. Debasis Sahu | Best Researcher Award

Fakir Mohan University | India

Dr. Debasis Sahu is a burgeoning researcher at the P.G. Department of Physics, Fakir Mohan University, Balasore (Odisha, India), whose research spans gravitation, cosmology, plasma cosmology and bio-physics. His scholarly profile (Google Scholar) currently shows an h-index of 2 with total citations of approximately 4. He holds an M.Phil. in Physics (Applied Physics & Ballistics) and is pursuing a doctoral research programme in the same university, during which he has co-authored peer-reviewed journal and conference papers, including “Generalized Interacting Dark Energy Model and Loop Quantum Cosmology” in Astrophysics & Space Science (2022) and work on interacting quintessence models (2020). His research interests include the dynamics of dark energy, black-hole physics in accelerating universes, loop quantum cosmology and cosmological implications of plasma interactions. He has actively engaged in workshops and conference proceedings focused on frontiers in high energy physics and cosmology. While formal awards for his work are not publicly listed, his contributions are positioned within the advancing frontier of theoretical cosmology. In conclusion, Dr. Sahu is an early-career researcher focused on deepening our understanding of dark-energy interactions and black-hole formation in non-standard cosmological frameworks, and his published work establishes a foundational platform for further academic growth.

Profiles : ScopusOrcid | Google Scholar

Featured Publications

Sahu, D., & Nayak, B. (2025). Fate of dark energy contaminated universe in standard cosmology. In Proceedings of the International Conference on Sustainable Science and Technology (ICSST 2025).

Sahu, D., & Nayak, B. (2025). CMBR constraint on black hole formation in standard cosmology. In Recent Trends in Applied Physics and Material Science (p. 143).

Sahu, D., & Nayak, B. (2025). Present matter density constraint on black hole formation. In 43rd Meeting of the Astronomical Society of India (ASI) (Poster 135).

Sahu, D., Swain, S., & Nayak, B. (2024). Deuterium photodisintegration constraint on black hole formation. In Proceedings of the DAE Symposium on Nuclear Physics, 68, 769.

Swain, S., Sahu, D., Sahoo, G., & Nayak, B. (2024). Helium abundance constraint on black hole formation. In Proceedings of the DAE Symposium on Nuclear Physics, 68, 815.

Assoc. Prof. Dr. Ateke Goshvarpour | Best Researcher Award

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Assoc. Prof. Dr. Ateke Goshvarpour | Best Researcher Award

Imam Reza International University | Iran

Ateke Goshvarpour is a distinguished researcher at Imam Reza International University, renowned for her extensive contributions to biomedical signal processing, emotion recognition, and neurophysiological data analysis. With an impressive h-index of 20, over 1,093 citations, and 70 research publications, her work has significantly advanced the integration of computational intelligence and physiological signal modeling. She has co-authored several influential studies on electroencephalography (EEG), electrocardiography (ECG), photoplethysmography (PPG), and galvanic skin response (GSR) for emotion and mental disorder recognition. Dr. Goshvarpour earned her higher education in biomedical engineering and has accumulated years of academic and research experience focusing on nonlinear analysis, chaos theory, and machine learning applications in healthcare. Her recent works explore quantum-inspired models, graph-based EEG analysis, and spectral–spatiotemporal fusion for diagnosing schizophrenia and cognitive disorders. She has been recognized for developing innovative feature fusion techniques that enhance accuracy in automated emotion recognition and neurodiagnostic systems. Her publications in high-impact journals such as Cognitive Neurodynamics, Chaos, Solitons & Fractals, and Biomedical Signal Processing and Control underscore her leadership in the field. Through her pioneering research, she continues to shape the future of computational neuroscience and affective computing, bridging the gap between biomedical engineering and mental health diagnostics.

Profiles : Scopus | Google Scholar

Featured Publications

Goshvarpour, A., Abbasi, A., & Goshvarpour, A. (2017). An accurate emotion recognition system using ECG and GSR signals and matching pursuit method. Biomedical Journal, 40(6), 355–368. https://doi.org/10.1016/j.bj.2017.10.001

Goshvarpour, A., & Goshvarpour, A. (2019). EEG spectral powers and source localization in depressing, sad, and fun music videos focusing on gender differences. Cognitive Neurodynamics, 13(2), 161–173. https://doi.org/10.1007/s11571-018-9510-8

Goshvarpour, A., Abbasi, A., & Goshvarpour, A. (2017). Fusion of heart rate variability and pulse rate variability for emotion recognition using lagged Poincaré plots. Australasian Physical & Engineering Sciences in Medicine, 40(3), 617–629. https://doi.org/10.1007/s13246-017-0560-7

Goshvarpour, A., & Goshvarpour, A. (2020). Schizophrenia diagnosis using innovative EEG feature-level fusion schemes. Physical and Engineering Sciences in Medicine, 43(1), 227–238. https://doi.org/10.1007/s13246-019-00853-8

Goshvarpour, A., & Goshvarpour, A. (2018). Poincaré’s section analysis for PPG-based automatic emotion recognition. Chaos, Solitons & Fractals, 114, 400–407. https://doi.org/10.1016/j.chaos.2018.07.009

Dr. Kalpana Panneerselvam | Dilute Magnetic Semiconductors | Best Researcher Award

Published on by Physics and Quantum Physics

Dr. Kalpana Panneerselvam | Dilute Magnetic Semiconductors | Best Researcher Award

Dr. Kalpana Panneerselvam | IIT Madras | India

Dr. Kalpana Panneerselvam is a distinguished researcher in Condensed Matter Physics, specializing in Nanomagnetism, Spintronics, Quantum Transport, and Thermoelectric Materials. Her research focuses on the theoretical understanding of diluted magnetic semiconductors (DMS), 2D-Xenes, and quantum-confined nanostructures, integrating quantum physics with semiconductor modeling. She has made notable contributions to the study of impurity states, exciton magnetic polarons, magneto-optical phenomena, and spin-polarized transport in low-dimensional systems. Her work on strain-engineered thermoelectric performance and Rashba spin–orbit coupling effects has advanced knowledge in nanoscale electronic transport and spin control. Dr. Panneerselvam has also explored light–matter interactions in photonic crystal waveguide cavities, linking nanophotonics with quantum computation. She employs computational tools such as Kwant, MATLAB, and FDTD simulations to model electronic and optical properties of emerging materials. Her publications in leading journals like Journal of Physics D: Applied Physics, European Physical Journal Plus, and Physica E highlight her innovative contributions. She has presented her work at major international forums, including the APS March Meeting and ICMAT, earning recognition for her clarity in theoretical modeling. A recipient of the Marie Skłodowska-Curie Fellowship Seal of Excellence, she has demonstrated exceptional academic excellence and research independence. Her doctoral work on impurity states in semimagnetic nanostructures was shortlisted among the best theses at the DAE Solid State Physics Symposium. With strong interdisciplinary expertise spanning quantum materials, spin-based electronics, and photonic devices, Dr. Panneerselvam continues to drive forward innovative approaches to understand and engineer next-generation quantum materials. She is an active member of the American Physical Society and Semiconductor Society of India, contributing meaningfully to global condensed matter and nanoscience research.

Profiles : Scopus |  Orcid | Google Scholar

Featured Publications

Panneerselvam, K., & Muralidharan, B. (2024). Giant excitonic magneto-optical Faraday rotation in single semimagnetic CdTe/Cd₁₋ₓMnₓTe quantum ring. Physica E: Low-Dimensional Systems and Nanostructures, 157, 115876.

Panneerselvam, K., & Muralidharan, B. (2024, June 18). Correction: Exciton magnetic polaron in Cd₁₋ₓMnₓTe single semimagnetic quantum ring. The European Physical Journal Plus.

Panneerselvam, K., & Muralidharan, B. (2024, April 8). Exciton magnetic polaron in Cd₁₋ₓMnₓTe single semimagnetic quantum ring. The European Physical Journal Plus, 139, 319.

Vignesh, G., Balaji, A. S., Mahalakshmi, S. M., Panneerselvam, K., & Mohan, C. R. (2023). On the semiconductor to metal transition in a quantum wire: Influence of geometry and laser. Modern Physics Letters B, 37(34), 2342007.

Panneerselvam, K., & Muralidharan, B. (2022). Exciton magnetic polaron in CdTe/Cd₁₋ₓMnₓTe single semimagnetic quantum ring. arXiv.

Panneerselvam, K., & Muralidharan, B. (2022). Modeling of exciton localization in semimagnetic concentric double quantum ring by the magnetic field. In Proceedings of the 2022 IEEE International Conference on Emerging Electronics (ICEE 2022) (pp. 1–5). IEEE.

Kalpana, P., & Jayakumar, K. (2021). Impurity states in semimagnetic quantum well wire with anisotropic confinement along in-plane directions. Journal of Experimental and Theoretical Physics, 130(2), 287–292.