Dr. Kousik Bera | Editorial Board Member

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Dr. Kousik Bera | Editorial Board Member

Indian Institute of Technology Bombay | India

Kousik Bera is an emerging researcher in optical physics and advanced materials science, with an h-index of 4, 11 research documents, and 48 citations across 44 citing works. He earned his research training at premier Indian institutions, focusing extensively on Raman spectroscopy, thermal transport in two-dimensional materials, nonlinear optics, and quantum photonics. His experience spans studies on hexagonal boron nitride (hBN), GaN nanowall networks, Heusler alloys, Pd–Ag nanostructures, and entangled photon generation using PPKTP crystals. He has contributed to prestigious journals such as Optics Communications, Physical Review B, Journal of Applied Physics, Applied Physics Letters, Optical Materials, and Nanotechnology. His research interests include 2D materials, ultrafast laser–matter interactions, spectroscopy-driven materials characterization, superconductivity, and quantum-enhanced optical systems. Bera’s work integrates experimental materials science with quantum photonic applications, highlighting his interdisciplinary expertise. His contributions have supported advancements in thermal conductivity engineering, strain analysis, nonlinear optical behavior, and surface-enhanced Raman spectroscopy (SERS). He has collaborated with multiple national and international research groups, extending the impact of his work across several domains of condensed matter physics. With a steadily growing publication record and diversified research output, he continues to advance innovative spectroscopic and nanomaterial-based methodologies.

Profiles : Google Scholar | Scopus Orcid

Featured Publications

Bera, K., Dubey, P. K., Kumar, A., & Jha, M. (2025). Bright source of degenerate polarization-entangled photons using type-0 PPKTP crystal: Effects of accidental coincidences. Optics Communications, 132401. https://doi.org/10.1016/j.optcom.2025.132401

Bera, K., Moram, S. S. B., Banerjee, D., Lahiri, J., & Rao Soma, V. (2024). Surface enhanced Raman scattering-based sensing and ultrafast nonlinear optical properties of silver-hexagonal boron nitride nanocomposites achieved by femtosecond laser ablation. Optical Materials, 157, 116393. https://doi.org/10.1016/j.optmat.2024.116393

Das, N. M., Chauhan, A., Bharati, M. S. S., Bera, K., et al. (2024). Nanostructured bi-metallic Pd–Ag alloy films for surface-enhanced Raman spectroscopy-based sensing application. Journal of Vacuum Science & Technology A, 42(5). https://doi.org/10.1116/6.0003748

Bera, K., Chugh, D., Bandopadhyay, A., Tan, H. H., Roy, A., & Jagadish, C. (2023). Decoupling the roles of defects/impurities and wrinkles in thermal conductivity of wafer-scale hBN films. Journal of Applied Physics, 134(15). https://doi.org/10.1063/5.0168186

Rahaman, A., Paramanik, T., Pal, B., Pal, R., Maji, P., Bera, K., et al. (2023). Surface-phase superconductivity in a Mg-deficient V-doped MgTi₂O₄ spinel. Physical Review B, 107(24), 245124. https://doi.org/10.1103/physrevb.107.245124

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

Mr. Abdul Majeed | Best Researcher Award

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Mr. Abdul Majeed | Best Researcher Award

University of Malakand | Pakistan

Dr. Abdul Majeed is a researcher at the Department of Physics, University of Malakand, specializing in quantum optics, quantum computation, mathematical physics, and plasmonics. His Google Scholar profile records an h-index of 3 with 30 citations across 11 documents. His research explores the coherent control of structured light, soliton dynamics, exceptional surfaces, tunneling effects, and Goos–Hänchen shifts in multi-level atomic and chiral media. He has co-authored several recent papers in leading journals such as Chaos, Solitons & Fractals, Applied Physics B, AIMS Mathematics, Scientific Reports, and Advanced Theory and Simulations, focusing on the theoretical modeling and manipulation of nonlinear optical and quantum phenomena. Dr. Majeed’s academic background includes studies in physics and applied mathematics, and he has experience in both research and teaching within higher education. His work demonstrates a strong grasp of light–matter interactions, plasmonic behavior, and quantum control mechanisms, contributing to the advancement of quantum photonics and optical communication technologies. Although major awards are not yet documented, his growing publication record and international collaborations highlight his emerging status as a promising physicist in theoretical and computational optics. In summary, Dr. Majeed’s contributions are expanding the understanding of quantum coherence and structured-light manipulation in complex media.

Profile : Google Scholar 

Featured Publications

Ullah, I., Majeed, A., & Ali, A., Khan, Z. A. (2025). Reflection and transmission solitons via high magneto optical medium. Chaos, Solitons & Fractals, 191, 115881.

Khan, Z. A., Majeed, A., Ullah, I., & Ali, A. (2025). Coherent generation of superluminal and subluminal propagation of structured light in five level atomic medium. Applied Physics B, 131(2), 30.

Ullah, I., Majeed, A., Dalam, M. E. E., Almazah, M. M. A., & Ali, A. (2025). Coherent manipulation of tunneling and super Gaussian based Goos–Hänchen shift in five level chiral atomic medium. Applied Physics A, 131(2), 89.

Emam, W., Majeed, A., Ali, Z., Ali, A., & Pamucar, D. (2025). Periodic dark and bright optical soliton dynamics in atomic medium governed by control fields of Milnor polynomial and super-Gaussian beam. International Journal of Theoretical Physics, 64(5), 141.

Majeed, A., Ullah, I., Alduais, F. S., Al Bossly, A., Bossly, R., & Ali, A. (2025). Investigation of rotary photon drag of generated structured light in a five level atomic medium. Advanced Theory and Simulations, 8(5), 2401307.

Assoc. Prof. Dr. Haiou Wang | Best Researcher Award

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Assoc. Prof. Dr. Haiou Wang | Best Researcher Award

Hangzhou Dianzi University | China

Dr. Haiou Wang is an accomplished Associate Professor at Hangzhou Dianzi University, China, specializing in spintronics and magnetic materials. He earned his Ph.D. in Physics from Nanjing University of Science and Technology in 2013 and has since established a strong academic and research career in condensed matter physics and materials science. Since joining Hangzhou Dianzi University in 2014, he has progressed from Assistant Professor to Associate Professor, contributing significantly to the study of magnetoresistance, magnetic phase transitions, and spin transport phenomena. Dr. Wang has published over 79 scientific documents, accumulating 690 citations with an h-index of 15, reflecting his consistent influence in the field. His notable works include studies on LaMnO₃, BaMnO₃, and Nd₁−ₓSrₓMnO₃ compounds, elucidating their structure–property relationships and magnetotransport mechanisms. Beyond his research contributions, Dr. Wang has served as a Guest Editor and Topic Editor for MDPI journals, demonstrating his leadership within the scholarly community. His research has been supported by the National Natural Science Foundation of China, highlighting his role in advancing materials for next-generation spintronic devices. Dr. Wang continues to pursue innovative research bridging magnetic materials and spintronics, contributing to the future of electronic and energy technologies.

Profiles : Scopus | Orcid 

Featured Publications

Li, J., Wang, H., & Wang, H. (2025). Structure, magnetism, and transport properties in hexagonal LaMnO₃. Journal of Electronic Materials. https://doi.org/10.1007/s11664-025-12473-7

Wang, H., Zhao, B., Tan, W., & Wang, H. (2025). Enhanced stability of lead-free CsSnI₃ perovskite through structural optimization. Journal of Materials Science: Materials in Electronics. https://doi.org/10.1007/s10854-025-15480-w

Wang, H., Li, J., & Wang, H. (2025). Magnetism, magnetoresistance, and temperature coefficient of resistance of the BaMnO₃ compound. Journal of Materials Science: Materials in Electronics. https://doi.org/10.1007/s10854-025-15446-y

Huang, S., Hua, J., Su, K., Yang, L., Wang, H., & Li, C. (2024). Anisotropic magnetoelectric effect in quasi-one-dimensional antiferromagnet Cu₃Mo₂O₉. Applied Physics Letters. https://doi.org/10.1063/5.0243143

Wang, H., Dong, F., Zhao, B., Tan, W., Huang, S., Su, K., Yang, L., & Wang, H. (2024). The colossal magnetoresistance within a wide temperature range in LaMnO₃ compound. Journal of Materials Science: Materials in Electronics. https://doi.org/10.1007/s10854-024-13490-8

Prof. Kazem Jamshidi-Ghale | Best Researcher Award

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Prof. Kazem Jamshidi-Ghale | Best Researcher Award

Azarbaijan Shahid Madani University | Iran

Prof. Kazem Jamshidi-Ghaleh is a distinguished physicist at the Department of Physics, Azarbaijan Shahid Madani University, Tabriz, Iran, with extensive experience in optics, photonics, and nonlinear optical phenomena. He holds a Ph.D. in Physics and has contributed over 50 peer-reviewed publications, accumulating more than 800 citations and an h-index of 19, reflecting his influential research in laser-matter interaction, nonlinear refraction, optical limiting, photonic crystals, and nanostructured thin films. Dr. Jamshidi-Ghaleh’s work spans experimental and theoretical studies on optical bistability, ultrafast laser processing, femtosecond laser interactions with materials, and the optical characterization of nanocomposites and dye molecules. He has led several projects on electrically tunable photonic devices and advanced optical measurement techniques such as moiré deflectometry. His research has been recognized in international journals including Optics Communications, Applied Physics A, and The European Physical Journal D. In addition to his research, he has mentored graduate students and collaborated with multidisciplinary teams on photonic materials and nanostructure applications. Dr. Jamshidi-Ghaleh continues to advance the field of photonics, contributing both fundamental insights and practical applications in optical materials and devices. His achievements highlight his commitment to scientific innovation, education, and the development of photonic technologies.

Profile : Google Scholar

Featured Publications

Jamshidi-Ghaleh, K., Salmani, S., & Ara, M. H. M. (2007). Nonlinear responses and optical limiting behavior of fast green FCF dye under a low power CW He–Ne laser irradiation. Optics Communications, 271(2), 551–554. https://doi.org/10.1016/j.optcom.2007.01.003

Tohidi, T., Jamshidi-Ghaleh, K., Namdar, A., & Abdi-Ghaleh, R. (2014). Comparative studies on the structural, morphological, optical, and electrical properties of nanocrystalline PbS thin films grown by chemical bath deposition using two different … Materials Science in Semiconductor Processing, 25, 197–206. https://doi.org/10.1016/j.mssp.2014.04.003

Jamshidi-Ghaleh, K., & Mansour, N. (2004). Nonlinear refraction measurements of materials using the moiré deflectometry. Optics Communications, 234(1–6), 419–425. https://doi.org/10.1016/j.optcom.2004.01.057

Mansour, N., Jamshidi-Ghaleh, K., & Ashkenasi, D. (2006). Formation of conical microstructures of silicon with picosecond laser pulses in air. Journal of Laser Micro/Nanoengineering, 1, 10.2961. https://doi.org/10.2961/jlmn.2006.1.10

Mohammad-Jafarieh, P., Akbarzadeh, A., Salamat-Ahangari, R., … Jamshidi-Ghaleh, K. (2021). Solvent effect on the absorption and emission spectra of carbon dots: Evaluation of ground and excited state dipole moment. BMC Chemistry, 15(1), 53. https://doi.org/10.1186/s13065-021-00789-1

Prof. Dr. Davron Juraev | Best Researcher Award

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Prof. Dr. Davron Juraev | Best Researcher Award

University of Economics and Pedagogy | Uzbekistan

Dr. Davron Aslonqulovich Juraev is a distinguished mathematician and researcher currently serving as a Research Fellow at the Scientific Research Center of Baku Engineering University, Azerbaijan. With an academic career spanning over a decade, he has previously held positions as Head of the Department of Natural Science Disciplines at the Higher Military Aviation School of the Republic of Uzbekistan and Associate Professor of Mathematics at Karshi State University. Dr. Juraev has authored 52 scientific documents, which have collectively received 449 citations and an h-index of 15, reflecting his growing international impact. His primary research interests encompass mathematical physics, partial differential equations, ill-posed problems, Cauchy problems, and spectral theory, with particular contributions to matrix factorization methods for the Helmholtz equation and inverse spectral problems. He has also explored fractal calculus, heat transfer models, and blockchain-based mathematical modeling. Dr. Juraev’s extensive collaborations with scholars worldwide have led to numerous high-impact publications in journals such as Symmetry, Engineering Reports, and Journal of Electronic Materials. His academic achievements underscore a profound dedication to advancing mathematical modeling and applied analysis, making him a recognized figure in theoretical and computational mathematics.

Profiles : Google Scholar | Orcid | Scopus

Featured Publications

 Juraev, D. A., Feyruz Efendiev, R., & Abdullaev, O. K. (2025). On an approximate solution of the Cauchy problem for the Helmholtz equation. Research in Mathematics, 2025(12-31). https://doi.org/10.1080/27684830.2025.2545036

Jamilov, U. U., Khamraev, A. Y., Norov, A. Z., Juraev, D. A., Nurhidayat, I., & Shah, M. A. (2025). On the family of non-constrained Volterra cubic operators. Research in Mathematics, 2025(12-31). https://doi.org/10.1080/27684830.2025.2528285

 Abdullayev, J. S., Sapaev, I. B., Abdullayev, J. S., Juraev, D. A., Jalalov, M. J., & Elsayed, E. E. (2025). Mathematical modeling of incomplete ionization in radial p-Si/n-GaAs heterojunctions: Temperature and doping effects. Journal of Electronic Materials, 54(11). https://doi.org/10.1007/s11664-025-12391-8

Abbasov, Z. D., Juraev, D. A., Abdullaev, O. K., Nurhidayat, I., & Shah, M. A. (2025). Heat transfer in n-dimensional parallelepipeds under zero Dirichlet conditions. Engineering Reports, 7(10). https://doi.org/10.1002/eng2.70458

 Efendiev, R. F., Juraev, D. A., & Elsayed, E. E. (2025). PT-symmetric Dirac inverse spectral problem with discontinuity conditions on the whole axis. Symmetry, 17(10), 1603. https://doi.org/10.3390/sym17101603

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

Dr. Kousik Bera | Best Paper Award

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Dr. Kousik Bera | Best Paper Award

Indian Institute of Technology Bombay | India

Dr. Kousik Bera is a research scholar at the Indian Institute of Technology Bombay, specializing in condensed matter physics, quantum materials, and spectroscopic techniques. He has authored 11 peer-reviewed publications, achieving over 45 citations with an h-index of 4, reflecting the quality and influence of his research. His work integrates Raman spectroscopy, ultrafast nonlinear optics, and quantum photonics to address key challenges in material science and quantum technology. Dr. Bera’s studies on wafer-scale hexagonal boron nitride (hBN) films have provided critical insights into the role of defects, wrinkles, and impurities in thermal transport, with implications for next-generation nanoelectronic devices. He has also contributed to the development of polarization-entangled photon sources using type-0 PPKTP crystals, advancing quantum communication and cryptography. His collaborative publications in Physical Review B, Journal of Applied Physics, Nanotechnology, Optical Materials, and Optics Communications highlight his multidisciplinary approach. With strong expertise in 2D materials, superconductivity, and quantum criticality, Dr. Bera’s research is paving the way for breakthroughs in photonic devices and quantum technologies. His academic productivity and impactful contributions make him a promising candidate for recognition and awards in physics and materials research.

Profile : Orcid

Featured Publications

Bright source of degenerate polarization-entangled photons using type-0 PPKTP crystal: Effects of accidental coincidences
Optics Communications, 2025 – Demonstrated a high-brightness entangled photon source, relevant for quantum communication and cryptography.

Surface-enhanced Raman scattering-based sensing and ultrafast nonlinear optical properties of silver–hexagonal boron nitride nanocomposites achieved by femtosecond laser ablation
Optical Materials, 2024 – Reported novel nanocomposites with enhanced SERS activity and nonlinear optical response for sensing applications.

Nanostructured bi-metallic Pd–Ag alloy films for surface-enhanced Raman spectroscopy-based sensing application
Journal of Vacuum Science & Technology A, 2024 – Developed bimetallic alloy films for ultrasensitive SERS-based detection.

Decoupling the roles of defects/impurities and wrinkles in thermal conductivity of wafer-scale hBN films
Journal of Applied Physics, 2023 – Provided critical insights into thermal transport mechanisms in large-area hBN films.

Surface-phase superconductivity in a Mg-deficient V-doped MgTi₂O₄ spinel
Physical Review B, 2023 – Investigated unconventional superconductivity and surface effects in spinel oxides.

Prof. Dr. Rami Ahmad El-Nabulsi | Physics Research Impact Award

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Prof. Dr. Rami Ahmad El-Nabulsi | Physics Research Impact Award

Dr. Rami Ahmad El-Nabulsi |  University of South Bohemia, Czech Republic

Dr. Rami Ahmad El-Nabulsi is a globally renowned theoretical physicist and applied mathematician, currently serving as a Senior Research Fellow at the Center of Excellence in Quantum Technology, Chiang Mai University, Thailand; the Department of Optical Networks, CESNET, Prague; and the University of South Bohemia, Czech Republic. With over 390 peer-reviewed journal publications, 6,700+ citations, and an h-index of 43, Dr. El-Nabulsi has established himself as a pioneer in nonlinear dynamics, quantum fractals, and interdisciplinary modeling in physical and engineering systems.

Author Profile

Google Scholar

Education

Dr. Rami Ahmad El-Nabulsi earned his Ph.D. in Mathematical Physics and Modeling from Aix-Marseille University (AMU), France, where he developed advanced analytical frameworks for nonlinear systems. He also holds a Diploma of Advanced Studies (DEA) in Plasma Physics from the same institution, reflecting his deep expertise in high-energy and space plasma phenomena. Prior to that, he completed both his Master’s and Bachelor’s degrees in Physics, building a solid foundation in classical and modern physics that underpins his interdisciplinary research today.

Professional Experience

Dr. El-Nabulsi holds multiple international research affiliations. At Chiang Mai University, he contributes to cutting-edge studies in quantum atom optics and fractal modeling of quantum phenomena. At CESNET and the University of South Bohemia, his research extends into computational modeling, nonlinear systems, and quantum technologies for networking and information systems.

He has published extensively on advanced topics such as nonlinear Hamiltonian systems, quantum chaos, fractal acoustics, and fractional calculus applied to astrophysical and material science problems. His theoretical research is complemented by strong computational skills and interdisciplinary collaborations across nuclear, space, and condensed matter physics.

Research Skills

Dr. El-Nabulsi’s expertise spans a wide range of advanced topics in physics and applied mathematics, including quantum and fractal dynamics, nonlinear differential equations, plasma magnetohydrodynamics (MHD), space physics, nuclear engineering, and superconductivity. He is particularly well-versed in fractional calculus and mathematical modeling, which he applies to develop novel theoretical frameworks for understanding complex systems. Proficient in a variety of computational tools such as MATLAB, Mathematica, Python, Fortran, C/C++, LaTeX, and Octave, Dr. El-Nabulsi brings a computational edge to his theoretical work. His unique contribution lies in constructing new mathematical models and physical theories that interpret phenomena across multiple scales—from subatomic interactions to cosmological structures—within fractal and fractional dimensions.

Selected Publications

Chaotic dynamics and fractal analysis of nonstandard Hamiltonian systems, Chaos, Solitons and Fractals, 2025

A model for ice sheets and glaciers in fractal dimensions, Polar Science, 2025

Structural Analysis of Phononic Crystals in Fractal Dimensions, Journal of Elasticity, 2025

Modeling Stochastic Langevin Dynamics in Fractal Dimensions, Physica A, 2025

A Fractional Model for Soliton in Low-Earth Orbital Plasma, IEEE Transactions on Plasma Science, 2025

Qualitative Financial Modelling in Fractal Dimensions, Financial Innovation, 2025

Time-Dependent Heating of the Solar Corona in Fractal Dimensions, Advances in Space Research, 2024

Higher-order Quantum Waves in Fractal Dimensions, Canadian Journal of Physics, 2024

Physics Research Impact

Dr. Rami Ahmad El-Nabulsi’s research has profoundly impacted the field of theoretical and applied physics, offering groundbreaking insights into the behavior of complex systems across quantum, classical, and cosmic scales. With a solid foundation in mathematical physics and nonlinear dynamics, his work uniquely blends fractal geometry, fractional calculus, and nonlocal variational principles to model physical phenomena that conventional approaches struggle to explain.

His contributions have advanced the theoretical understanding of quantum chaos, Hamiltonian mechanics, and nonlinear wave propagation in fractal dimensions. Dr. El-Nabulsi’s innovative approaches have been applied to diverse fields including plasma magnetohydrodynamics (MHD), quantum electronics, astrophysics, superconductivity, and nuclear fusion physics. Notably, his models on magnetic chaotic field lines in fusion reactors, solar corona heating, and quantum waves in nonlocal geometries offer new perspectives for tackling real-world engineering and astrophysical problems.

Research Interests

Dr. El-Nabulsi’s research interests encompass a diverse and interdisciplinary array of topics, including quantum mechanics in fractal dimensions, geometrical and nonlinear dynamics, and chaos theory. He is deeply engaged in exploring fundamental theories such as general relativity and quantum field theory, while also contributing to applied domains like plasma physics, superconductivity, and mathematical modeling. His work extends to emerging fields such as fractal thermodynamics, multiscale physics, and biophysics, with additional focus on reactor and nuclear systems as well as acoustic metamaterials. This broad scope reflects his commitment to advancing theoretical understanding and practical applications across multiple branches of modern physics.

Conclusion

Dr. Rami Ahmad El-Nabulsi is a multidisciplinary scholar who continues to push the boundaries of theoretical physics and applied mathematics. His passion for scientific exploration, teaching, and global collaboration contributes profoundly to understanding the complex nonlinear structures that govern our universe — from the quantum to the cosmic scale.