Mr. Shehzad Khan | Best Researcher Award

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Mr. Shehzad Khan | Best Researcher Award

Nanjing University of Science and Technology | China

Mr. Shehzad Khan is a promising Pakistani quantum physicist with a growing research profile in the fields of quantum optics, quantum information, plasmonics, and nonlinear optics. With an h-index of 2, 3 published documents, and 7 citations, he has contributed to several high-impact journals, including Results in Physics, The European Physical Journal Plus, International Journal of Theoretical Physics, Journal of Magnetism and Magnetic Materials, and Physics Letters A. He completed his Bachelor’s degree in Physics from the University of Malakand (2019–2023), where his thesis focused on “Manipulation of Spectral Hole Burning in Atomic Medium by Doppler Broadening Effect.” His research expertise includes density matrix formalism, optical solitons, Goos-Hänchen shift, photonic spin Hall effect, and surface plasmon polaritons. Shehzad has demonstrated strong analytical and computational skills using Mathematica, MATLAB, and LaTeX, coupled with proficiency in data analysis and technical writing. Recognized for his academic excellence, he received the Higher Education Commission (HEC) Laptop Award for outstanding performance and an HEC Merit and Need-Based Scholarship. With a clear vision to advance the understanding of light-matter interaction and quantum systems, Shehzad Khan aspires to make impactful contributions to modern quantum science and optical physics.

Profile : Scopus

Featured Publications

Khan, S., Bilal, M., Uddin, S., Akgül, A., & Riaz, M. B. (2024). Spherical manipulation of lateral shifts in reflection and transmission through chiral medium. Results in Physics, 107647.

Khan, S., Saeed, M., Khan, M. A., Aldosary, S. F., & Ahmad, S. Coherent manipulation of optical solitons in four-level N-type atomic medium. International Journal of Theoretical Physics.

Ullah, R., Khan, S., Amina, S., & Javaid, S. Tunable cratering of lateral Goos–Hänchen shift in reflection and transmission of structured light in a chiral atomic medium. The European Physical Journal Plus.

Ullah, H., Khan, S., & Bilal, M. Localized electric and magnetic tangent loss via parity-time symmetry in induced high magneto-optical atomic medium. Journal of Magnetism and Magnetic Materials.

Ahmad, M., Khan, S.*, Shah, S. M. H., Salman, M., & Yousaf, M. (2025). Coherent manipulation of sensitivity of structure plasmon polariton waves. The European Physical Journal Plus.

Dr. Michael Mercier | Best Researcher Award

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Dr. Michael Mercier | Best Researcher Award

University of Corsica | France

Dr. Michaël Mercier-Finidori is a French physicist and lecturer at the University of Corsica Pascal Paoli (UMR CNRS 6134 SPE), renowned for his contributions to the fields of underwater acoustics, ultrasound, group theory, and mathematical physics. He obtained his Ph.D. in Sciences pour l’Environnement from UMR CNRS 6134 SPE in 2002, where he developed a strong foundation in acoustic wave propagation and elastic scattering. Since joining the University of Corsica in 2003, Dr. Mercier-Finidori has actively engaged in both teaching and advanced research, focusing on acoustic scattering phenomena in elliptical geometries and elastic shells. His scholarly output includes six peer-reviewed publications that have collectively garnered 12 citations from 10 documents, with an h-index of 3, reflecting his impactful and specialized work. His recent open-access article, Acoustic scattering by elliptical elastic shells: Exact formalism and physical interpretation (Journal of Sound and Vibration, 2025), exemplifies his analytical rigor and innovative approach to acoustic modeling. Dr. Mercier-Finidori’s research provides valuable insights for applications in sonar technology, materials characterization, and acoustic signal analysis. His sustained academic commitment and theoretical depth underscore his influence in advancing the understanding of elastic wave dynamics in complex geometries.

Profiles : Orcid | Scopus

Featured Publications

Ancey, S., Gabrielli, P., & Mercier, M. (2025). Acoustic scattering by elliptical elastic shells: Exact formalism and physical interpretation. Journal of Sound and Vibration, 619, 119341. https://doi.org/10.1016/j.jsv.2025.119341

Ancey, S., Bazzali, E., Gabrielli, P., & Mercier, M. (2014). Acoustic scattering by elastic cylinders of elliptical cross-section and splitting up of resonances. Journal of Applied Physics, 115(19), 194901. https://doi.org/10.1063/1.4876678

Bazzali, E., Ancey, S., Gabrielli, P., & Mercier-Finidori, M. (2013). Splitting up resonances of elastic elliptical disc. Proceedings of Meetings on Acoustics, 19(1), 045002. https://doi.org/10.1121/1.4799566

Ancey, S., Bazzali, E., Gabrielli, P., & Mercier, M. (2013). Elastodynamics and resonances in elliptical geometry. Journal of Physics A: Mathematical and Theoretical, 46(43), 435204. https://doi.org/10.1088/1751-8113/46/43/435204

Gabrielli, P., & Mercier-Finidori, M. (2002). Multiple scattering by two impenetrable cylinders: Semiclassical theory. Physical Review E, 66(4), 046629. https://doi.org/10.1103/PhysRevE.66.046629

Prof. Dr. Galina Makeeva | Best Researcher Award

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Prof. Dr. Galina Makeeva | Best Researcher Award

Penza State University | Russia

Dr. Galina Makeeva is a highly accomplished physicist and researcher at the University of Penza, Russian Federation, specializing in terahertz photonics, graphene plasmonics, and magneto-optical materials. With an impressive research portfolio of 115 scientific publications, her studies have garnered 236 citations and an h-index of 8, demonstrating her sustained impact in the field. Dr. Makeeva’s research focuses on the theoretical modeling and numerical simulation of electromagnetic wave interactions with advanced nanostructures such as graphene nanoribbons, metasurfaces, and nonlinear semiconductor systems. Her pioneering work on magnetically tunable and electrically controllable metasurfaces has opened new pathways for developing next-generation terahertz and mid-infrared optoelectronic devices. She has published extensively in top-tier journals including Optics and Spectroscopy, Technical Physics, and the Journal of Experimental and Theoretical Physics. Through her contributions, Dr. Makeeva has advanced the understanding of graphene-based photonic platforms, bridging the gap between classical electromagnetics and emerging nanophotonic technologies. Her innovative and interdisciplinary research continues to shape the evolution of high-frequency devices and photonic materials. Recognized for her academic excellence and scientific rigor, Dr. Makeeva remains at the forefront of developing functional materials for next-generation communication and sensing technologies.

Profile : Scopus

Featured Publications

Makeeva, G. S. (2025). Magnetoplasmonic effects induced by diffraction of terahertz waves on magnetically biased graphene metasurfaces. Journal of Experimental and Theoretical Physics.

Makeeva, G. S. (2025). Tunable polarization magnetooptical effects at scattering of terahertz radiation from graphene nanoribbon gratings in a magnetic field. Journal of Experimental and Theoretical Physics.

Makeeva, G. S. (2025). Numerical simulation of scattering patterns of terahertz waves on graphene nanoribbon arrays in a magnetic field. Technical Physics.

Makeeva, G. S. (2025). Method of nonlinear autonomous blocks with Floquet channels for simulation of nonlinear microwave devices with distributed interaction. Technical Physics.

Makeeva, G. S. (2025). Numerical investigation of the diffraction field of terahertz waves on graphene nanoribbons upon applying a magnetic field. Technical Physics.

Mr. Zahid Ullah | Best Researcher Award

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Mr. Zahid Ullah | Best Researcher Award

Islamia College University Peshawar | Pakistan 

Dr. Zahid Ullah is a computational materials scientist currently serving as a Scholar at Qurtuba University of Science and Information Technology, Peshawar, and pursuing his PhD in Physics at Islamia College Peshawar. With an h‑index of 12, over 1,100 citations, and multiple high-impact publications, he has established a strong presence in theoretical and computational condensed matter physics. His research focuses on first-principles calculations, employing density functional theory (DFT) and WIEN2k/CASTEP computational frameworks to investigate the structural, electronic, thermoelectric, and magnetic properties of materials such as spinels (MgGa₂O₄, ZnAl₂O₄) and ternary tellurides (KAlTe₂, KInTe₂). He has contributed significantly to understanding energy‑conversion materials, magnetic semiconductors, and thermoelectric performance, guiding experimental and theoretical developments for sustainable energy solutions and advanced electronic/spintronic applications. Notable publications include studies on high-temperature thermoelectric performance of MgGa₂O₄ and the electronic and magnetic characteristics of KAlTe₂ and KInTe₂. His work integrates materials informatics with computational modeling to predict and optimize material behaviors. Dr. Ullah’s ongoing research aims to design next-generation functional materials, and he is recognized for his early-career contributions to computational materials science. His efforts provide critical insights that bridge fundamental physics with practical applications in energy, electronics, and spintronics.

Profiles : Orcid | Google Scholar

Featured Publications

Ullah, Z., Khan, R., Khan, M. A., Al Otaibi, S., Althubeiti, K., & Abdullaev, S. (2025). High-temperature thermoelectric performance of spinel MgGa2O4 through a first-principles and Boltzmann transport study. Computational Materials Science, 259, 114163. https://doi.org/10.1016/j.commatsci.2025.114163

Ullah, Z., Amir, M., Bazilla, A., Ullah, S., Shahzad, U., Ullah, N., Khan, J., & Gul, S. (2024). Electronic, thermoelectric and magnetic properties of ternary telluride KAlTe2 and KInTe2 from theoretical perspective. Next Research, 1(2), 100077. https://doi.org/10.1016/j.nexres.2024.100077

Khan, M. A., & Ullah, Z. (2025). First-principles study of electronic, structural, and thermoelectric nature. Theoretical Chemistry Accounts, 144(8), 61. https://doi.org/10.1007/s00214-025-03000-0

Ullah, Z., Khan, M. A., Gul, S., Noman, M., Ullah, S., & Shahab, M. (2025). Remarkable thermoelectric and magnetic properties of anti-perovskite MgCNi3: A pathway to advanced energy conversion and spintronics. Journal of Superconductivity and Novel Magnetism, 38(4), 167. https://doi.org/10.1007/s10948-025-08800-5

Ullah, Z., & Khan, M. A. (2025). First-principles study of ZnAl2O4 for energy applications. International Journal of Modern Physics B, 2550270. https://doi.org/10.1142/S0217979225502704

Dr. Ahmed Zahia | Best Researcher Award

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Dr. Ahmed Zahia | Best Researcher Award

Benha University | Egypt

Dr. Ahmed Zahia is an Assistant Lecturer in the Department of Mathematics at Benha University, Egypt. He earned his Bachelor of Science in Mathematics from Benha University in 2020 and has been actively engaged in teaching and research since 2020. His research lies at the intersection of applied mathematics and quantum physics, focusing on quantum information, quantum correlations, quantum mechanics, and dynamical systems. With a growing reputation in theoretical and computational quantum studies, Zahia has authored nine research papers in internationally recognized journals such as Scientific Reports, Journal of Physics A, Physica Scripta, Optical and Quantum Electronics, EPJ Quantum Technology, and Thermal Science. His work explores topics including entanglement dynamics, quantum steering, quantum batteries, and information scrambling in multi-qubit and multi-mode systems. His publications have collectively received 27 citations from 20 documents, reflecting an h-index of 3. Zahia is also passionate about science communication, running a YouTube channel dedicated to teaching mathematics. Through his contributions, he continues to advance understanding of quantum information processing and the interplay between entanglement, coherence, and energy transfer in quantum systems, marking him as a promising emerging researcher in applied and theoretical quantum mechanics.

Profiles : Orcid | Google Scholar | Scopus

Featured Publications

Zahia, A. A., Khalil, E., & Al-Awfi, S. (2025). Entanglement and steering of three-mode field in trio coherent states. International Journal of Theoretical Physics, 64(9), 226. https://doi.org/10.1007/s10773-025-06072-9

Zahia, A. A. (2025). Optimizing quantum battery performance: A comparative study of parallel and series charging protocols. Physica Scripta, 100(8), 085501. https://doi.org/10.1088/1402-4896/adee67

Zahia, A. A., Saad, H. M., Ali, S. I., Ahmed, M. M. A., & Obada, A.-S. F. (2025). Quantum information metrics of a multi-level atom interacting with an SU(1,1) quantum amplifier system. EPJ Quantum Technology, 12(1), 90. https://doi.org/10.1140/epjqt/s40507-025-00394-7

Abd-Rabbou, M. Y., Zahia, A. A., Rahman, A. U., & Qiao, C. F. (2025). The limits of quantum information scrambling. Journal of Physics A: Mathematical and Theoretical, 58(25), 255301. https://doi.org/10.1088/1751-8121/ade1b9

Zahia, A. A., Abd-Rabbou, M. Y., & Megahed, A. M. (2025). Entanglement-driven energy exchange in a two-qubit quantum battery. Journal of Physics B: Atomic, Molecular and Optical Physics, 58(6), 065501. https://doi.org/10.1088/1361-6455/adbc56

Prof. Jean-Patrick Connerade | Best Researcher Award

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Prof. Jean-Patrick Connerade | Best Researcher Award

Imperial College London | United Kingdom

Jean-Patrick Connerade is an Emeritus Professor of Physics at Imperial College London and a distinguished member of the European Academy of Sciences, Arts and Letters (EASAL) in Paris. He holds a Doctor of Science (D.Sc.) degree from the University of London and has made pioneering contributions to atomic and molecular physics, particularly in the study of quantum confinement, atomic structure, and resonances in confined atoms and ions. Over his illustrious career, Professor Connerade has published more than 213 scientific documents, amassing 4,363 citations and achieving an impressive h-index of 30, reflecting his enduring impact on the global scientific community. His notable works include “The Arrow of Time in Quantum Theory” (2025), “The Atom at the Heart of Physics” (2023), and studies on C₆₀ spin-charging and confinement resonances. A prolific author and thought leader, he has contributed extensively to understanding the fundamental behavior of atoms under confinement and the crossover between simple and complex quantum systems. Recognized internationally for his scholarship, Professor Connerade continues to inspire physicists worldwide through his deep insights into atomic theory and his leadership in advancing interdisciplinary research in quantum and optical physics.

Profiles : Orcid | Scopus

Featured Publications

Connerade, J. P. (2025). The arrow of time in quantum theory. Atoms, 13(11), 86. https://doi.org/10.3390/atoms13110086

Connerade, J. P. (2023). The atom at the heart of physics. Atoms.

Connerade, J. P. (2021). A new angle on resonances in confined atoms and ions. Physica Scripta.

Connerade, J. P. (2018). On the perturbation of the 6snd 1,3D₂ series by the 5d7d 1D₂ state of barium. Laser Physics.

Connerade, J. P. (2015). C₆₀ spin-charging with an eye on a quantum computer. Journal of Physics B: Atomic, Molecular and Optical Physics.

Connerade, J. P. (2010). Initial considerations on the relationship between the optical absorption and the thermal conductivity in dielectrics. Journal of Physics D: Applied Physics.

Dr. Muhammad Noman | Best Researcher Award

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Dr. Muhammad Noman | Best Researcher Award

South China University of Technology | Pakistan

Muhammad Noman is a dedicated researcher pursuing his Ph.D. in Quantum Information and Computation at the South China University of Technology, Guangzhou, China. His academic journey began at the University of Malakand, Pakistan, where he conducted research in the Department of Physics, laying a strong foundation in theoretical and quantum physics. His research focuses on quantum information theory, decoherence dynamics, open quantum systems, and quantum correlations in multipartite states. He has authored eight peer-reviewed journal articles in prestigious international journals, including Journal of Physics B, Physica Scripta, Laser Physics, and International Journal of Modern Physics A. His contributions to understanding quantum coherence under various environmental influences have garnered over 100 citations across 8 publications, with an h-index of 6. His recent works explore dissipative environments, Heisenberg models, and gravitational cat states, expanding the frontiers of quantum dynamics. Recognized for his strong analytical skills and innovative theoretical modeling, Muhammad Noman is emerging as a promising scholar in quantum computation and quantum optics. His academic achievements and research impact reflect a commitment to advancing the fundamental understanding of quantum systems and their real-world applications.

Profiles : Orcid | Google Scholar

Featured Publications

Noman, M., Mazhar, A., & Cui, W. (2025). Two-spin Heisenberg model driven by joint magnetic-dephasing field. International Journal of Modern Physics A, 40(25), 2550089. https://doi.org/10.1142/S0217751X25500897

Manan, A., Noman, M., Ali, H., & Haddadi, S. (2025). Qubit–Qutrit coherence dynamics under a dissipative environment. Laser Physics, 35(4), 045206. https://doi.org/10.1088/1555-6611/adc557

Sarkar, R., Manan, A., Noman, M., & Zangi, S. M. (2025). Effects of various interactions on gravitational cat states under amplitude damping noise. International Journal of Theoretical Physics, 64(4), 81. https://doi.org/10.1007/s10773-025-05945-3

Noman, M., Shah, K., Kenfack, L. T., Cui, W., & Rahman, A. U. (2025). Quantum correlations dynamics in qubit–qutrit system under magnetic and dephasing field. Journal of Physics B: Atomic, Molecular and Optical Physics, 58(1), 015502. https://doi.org/10.1088/1361-6455/ad9a9f

Noman, M., Kenfack, L. T., & Cui, W. (2024). Bipartite quantum features influenced by pure and mixed disorders. Physica Scripta, 99(10), 105127. https://doi.org/10.1088/1402-4896/ad7aab

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

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.

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

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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.