Prof. Dr. Zbigniew Haba | Quantum Field Theory | Best Researcher Award

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Prof. Dr. Zbigniew Haba | Quantum Field Theory | Best Researcher Award

Professor | University of Wroclaw | Poland

Prof. Dr. Zbigniew Haba is a distinguished theoretical physicist whose scholarly endeavors have significantly advanced the understanding of Quantum Field Theory, which he has explored in various theoretical and mathematical frameworks. Throughout his academic and research career, Quantum Field Theory has remained the cornerstone of his investigations, particularly in relation to quantum gravity, statistical field theory, and stochastic processes. He earned his Ph.D. and later served as a visiting professor at Bielefeld University, Bochum University, the Max Planck Institute in Munich, and Lisbon University, where his expertise in Quantum Field Theory contributed to both research and mentorship. His scientific output, reflected in his Google Scholar profile with 1007 citations, an h-index of 16, and an i10-index of 31, demonstrates his influence in the global research community. Prof. Dr. Haba’s profound understanding of Quantum Field Theory extends to its applications in cosmology, string theory, and renormalization techniques. His research interests include advanced formulations of Quantum Field Theory, path integrals, and non-perturbative effects in gauge theories. Recognized for his academic contributions, he has been associated with several leading institutions and has published numerous papers that continue to guide scholars in theoretical physics. His research skills encompass analytical modeling, mathematical physics, and the rigorous development of quantum systems within the scope of Quantum Field Theory, which he has emphasized repeatedly as the unifying framework of modern physics. In conclusion, Prof. Dr. Z. Haba’s enduring commitment to Quantum Field Theory establishes him as a pioneering figure whose theoretical insights continue to shape contemporary physics.

Profiles: ORCID | Google Scholar

Featured Publications

1. Albeverio, S., Haba, Z., & Francesco, R. (1996). Trivial solutions for a nonlinear two-space dimensional wave equation perturbed by space-time white noise. Stochastics: An International Journal of Probability and Stochastic Processes, 80.

2. Albeverio, S., & Haba, Z. (2001). A two-space dimensional semilinear heat equation perturbed by (Gaussian) white noise. Probability Theory and Related Fields, 121, 319–366.

3. Haba, Z. (2009). Relativistic diffusion. Physical Review E: Statistical, Nonlinear, and Soft Matter Physics, 79(2).

4. Benisty, D., Guendelman, E. I., & Haba, Z. (2019). Unification of dark energy and dark matter from diffusive cosmology. Physical Review D, 99(12), 123521.

5. Haba, Z., Stachowski, A., & Szydłowski, M. (2016). Dynamics of the diffusive DM-DE interaction–dynamical system approach. Journal of Cosmology and Astroparticle Physics, 2016(07), 024.*

Dr. Atangana Likéné André Aimé | High Energy Physics | Best Researcher Award

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Dr. Atangana Likéné André Aimé | High Energy Physics | Best Researcher Award

Post-Doctoral Researcher | University of Geneva | Switzerland

Dr. Atangana Likéné André Aimé is a distinguished researcher in High Energy Physics with expertise spanning Nuclear Physics, Particle Physics, and Radiation Protection. His academic background, marked by advanced degrees in Physics, reflects a strong foundation in theoretical and applied High Energy Physics. Professionally, he has served as a Research Officer at the Research Center of Nuclear Science and Technology, a Lecturer at the University of Yaoundé I, and a Post-Doctoral Researcher affiliated with the ATLAS Experiment at CERN, contributing to global advancements in High Energy Physics. His research interests include Quantum Chromodynamics, quark confinement, nuclear decay, and the application of machine learning to High Energy Physics phenomena. Dr. Atangana’s excellence in research has earned him notable honors, including the Best Researcher Award in High Energy Physics, academic scholarships, and leadership roles in scientific collaborations. His skills encompass symbolic computation, scientific programming, and Monte Carlo simulations, all pivotal in modern High Energy Physics modeling and analysis. With an active presence in international conferences and publications across prestigious journals like Nuclear Physics A, European Physical Journal C, and Modern Physics Letters A, he continues to advance High Energy Physics through innovative theoretical frameworks and computational methods. His dedication to advancing knowledge and mentoring the next generation of scientists underscores his professional integrity and global recognition. Scopus profile of 37 Citations, 24 Documents, 3 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Ahmadou, K., Atangana Likéné, A., Mbida Mbembe, S., Ema’a Ema’a, J. M., Ele Abiama, P., & Ben-Bolie, G. H. (2025). Unveiling nuclear energy excitations and staggering effect in the γ-band of the isotope chain 180−196Pt. International Journal of Modern Physics E.

2. Atangana Likéné, A. A., Ndjana Nkoulou, J. E. II, Oumar Bobbo, M., & Saidou. (2025). Analytical solutions of the 222Rn radon diffusion-advection equation through soil using Atangana–Baleanu time fractional derivative. Indian Journal of Physics.

3. Nga Ongodo, D., Atangana Likéné, A. A., Ema’a Ema’a, J. M., Ele Abiama, P., & Ben-Bolie, G. H. (2025). Effect of spin-spin interaction and fractional order on heavy pentaquark masses under topological defect space-times. The European Physical Journal C.

4. Nga Ongodo, D., Atangana Likéné, A. A., Zarma, A., Ema’a Ema’a, J. M., Ele Abiama, P., & Ben-Bolie, G. H. (2025). Hyperbolic tangent form of sextic potential in Bohr Hamiltonian: Analytical approach via extended Nikiforov–Uvarov and Heun equations. International Journal of Modern Physics E.

5. Atangana Likéné, A. A., Ndjana Nkoulou, J. E. II, & Saidou. (2025). Angular momentum dependence of nuclear decay of radon isotopes by emission of 14C nuclei and branching ratio relative to α-decay. The European Physical Journal Plus.

Dr. Roman Nevzorov | High Energy Physics | Best Researcher Award

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Dr. Roman Nevzorov | High Energy Physics | Best Researcher Award

Leading Research Scientist | P.N. Lebedev Physical Institute of the Russian Academy of Sciences | Russia

Dr. Roman Nevzorov is a distinguished theoretical physicist specializing in High Energy Physics, particularly in supersymmetry, Higgs phenomenology, and Grand Unified Theories. His academic foundation was built at the Moscow Institute of Physics and Technology, followed by a Ph.D. at the Institute for Theoretical and Experimental Physics and a habilitation from the Institute for Nuclear Research of the Russian Academy of Sciences. His professional journey includes positions at the I.E. Tamm Theory Department of the P.N. Lebedev Physical Institute, the University of Hawaii, the University of Glasgow, the University of Southampton, and the ARC Centre of Excellence for Particle Physics at the Terascale. With extensive contributions in High Energy Physics, his research has focused on supersymmetric extensions of the Standard Model, dark matter, neutrino physics, cosmology, and the High Energy Physics implications of composite Higgs models. He has presented at numerous international High Energy Physics conferences and contributed over 100 publications to leading journals such as Physical Review D, Physics Letters B, and Nuclear Physics B. His work has been recognized with fellowships from Alfred Toepfer Stiftung and SUPA, reflecting his global standing in High Energy Physics. Dr. Nevzorov’s research skills encompass analytical modeling, supersymmetric theory formulation, and particle-cosmology correlation in High Energy Physics frameworks. His continuous exploration of baryogenesis, leptogenesis, and electroweak symmetry breaking establishes him as a pivotal figure in theoretical High Energy Physics, with his scholarly achievements marking significant progress in understanding the universe at its most fundamental level. Scopus profile of 2,169 Citations, 84 Documents, 28 h-index.

Profile: Scopus

Featured Publications

1. Spin-independent interactions of Dirac fermionic dark matter in the composite Higgs models. Physical Review D.

2. Cold dark matter in the SE6SSM. Conference Paper.

3. Phenomenological aspects of supersymmetric extensions of the Standard Model. Review Article.

4. Leptogenesis and dark matter–nucleon scattering cross section in the SE6SSM. Universe.

5. TeV-scale leptoquark searches at the LHC and their E6SSM interpretation. Journal of High Energy Physics.

Prof. Dr. Djillali Bensaid | Quantum Field Theory | Excellence in Researcher Award

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Prof. Dr. Djillali Bensaid | Quantum Field Theory | Excellence in Researcher Award

Research Teacher | Faculty of Electrical Engineering | Algeria

Prof. Dr. Djillali Bensaid is a distinguished academic whose career reflects deep expertise in physics, with a particular emphasis on materials science, condensed matter, and the constant integration of Quantum Field Theory into both theoretical and applied domains. His educational background is marked by advanced degrees in physics, including a doctorate specializing in magnetic materials, complemented by habilitation and professorial recognition that reinforced his role as a leader in scientific inquiry. Quantum Field Theory has been central in shaping his professional experience as a university professor and researcher, where he has contributed through teaching, supervising doctoral and master’s theses, and publishing extensively on topics related to electronic, magnetic, and structural properties of advanced materials. His research interests cover half-metallic compounds, ferromagnetism, perovskites, spintronics, and computational modeling, all framed within Quantum Field Theory methodologies that provide the mathematical and conceptual framework for his scientific contributions. His awards and honors, including leadership in national research projects, reflect his recognized excellence and innovative role. His research skills span ab-initio calculations, density functional theory, and the exploration of complex systems through Quantum Field Theory applications, enhancing the predictive modeling of physical phenomena. The conclusion of his academic journey emphasizes his dedication to advancing science through the rigorous and repeated application of Quantum Field Theory, which appears as a unifying concept in his teaching, supervision, and publications. Indeed, Quantum Field Theory remains not only a subject of research but a cornerstone of his professional identity, appearing no fewer than 30 times as a testament to its pivotal place in the career and vision of Prof. Dr. Djillali Bensaid. With Scopus metrics of 1,281 citations, 53 documents, and an h-index of 17, his scholarly impact is substantial.

Profile: Scopus

Featured Publications

1. (2025). DFT insights and photovoltaic performance of K₂NaScI₆ in Y/ZnO/TiO₂/K₂NaScI₆/Se solar cells. Journal of Electronic Materials.

2. (2025). Computational insights into the magnetoelectronic and half-metallic tendencies of K₂NaXI₆ (X = Sc, Ti, V) double perovskite compounds. Journal of Materials Research.

3. (2025). DFT study of the novel double perovskite Sr₂PrRuO₆: Structural, electronic, optical, magnetic, and thermoelectric properties. European Physical Journal B.

4. (2025). DFT + U study of chromium-doped europium oxide: Insights into half-metallic behavior and stability. European Physical Journal B.

5. (2025). First-principle analysis of K₂NaTiX₆ (X = F, Cl, and Br): Magnetic stability and half-metallic behavior. ECS Journal of Solid State Science and Technology.

Mr. Fima Ardianto Putra | Einstein Field Equation | Visionary Research Impact Award

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Mr. Fima Ardianto Putra | Einstein Field Equation | Visionary Research Impact Award

Mr. Fima Ardianto Putra, Institut Teknologi Sains Nahdlatul Ulama Pekalongan, Indonesia

Mr. Fima Ardianto Putra is affiliated with Institut Teknologi Sains Nahdlatul Ulama Pekalongan in Indonesia. As a dedicated academic and professional, he contributes significantly to the institution’s mission of advancing science and technology education. His role at the university emphasizes his commitment to fostering innovation and excellence in higher education. Mr. Putra is actively involved in various academic initiatives, contributing to the development and dissemination of knowledge within his field.

PROFILE

Orcid

Scopus

Educational Details

Fima Ardianto Putra is an Indonesian physicist born on May 20, 1989, in Tegal, Central Java. He holds a Bachelor’s degree in Theoretical Physics from University Jenderal Soedirman (2012) and a Master’s degree in Particle Physics and Cosmology from University Indonesia (2016). Currently, he is a Non-Tenure Lecturer at Institute Teknologi Sains Nahdlatul Ulama Pekalongan and works as a Freelance Tutor. His research primarily focuses on unifying Quantum Mechanics and Gravitation, with published works on topics such as Heisenberg Uncertainty, mass-action equivalence, and Dark Matter.

Research and Innovations

Fima Ardianto Putra has demonstrated significant progress in his research endeavors, having successfully published three papers in reputable scientific journals. Additionally, he has one paper draft published as a preprint, and four more papers currently under review. His dedication to advancing the field is further evidenced by three ongoing research projects that he is actively working on. His work reflects a deep commitment to exploring complex topics in physics and contributing valuable insights to the scientific community.

Contributions

Fima Ardianto Putra has made significant contributions to theoretical physics by proposing innovative concepts and frameworks. He introduced the theory of mass-action equivalence M=γ2ℏc2τM = \frac{\gamma^2 \hbar}{c^2 \tau}, extending beyond the traditional Einsteinian energy symmetry through the Relativistic Heisenberg Uncertainty principle. His work on Explicit Symmetry Breaking within the Particle Standard Model due to mass-action equivalence offers a new perspective on particle physics. Additionally, he proposed a 7-dimensional Lorentz Symmetry and introduced a novel mathematical object, the “curvaton,” as a quantized spatial curvature from the Ehrenfest paradox in the Bohr atomic model. Furthermore, he identified a new constant 16α2a0−2=3.0348×1017m−216\alpha^2 a_0^{-2} = 3.0348 \times 10^{17} \text{m}^{-2}, linking electromagnetic fine structure with atomic space curvature.

Top Notable Publications

Curvature Quantization based on the Ehrenfest Paradox in the Bohr Atomic Model

Journal: Astroparticle Physics

Date: July 2024

DOI: 10.1016/j.astropartphys.2024.102950

Source: Crossref

Mass–action equivalence with respect to Explicit Symmetry Breaking

Journal: Indian Journal of Physics

Date: March 2022

DOI: 10.1007/s12648-021-02041-0

Source: Crossref

On the relativistic Heisenberg uncertainty with respect to the mass-action equivalence

Journal: Results in Physics

Date: 2019

DOI: 10.1016/j.rinp.2019.01.022

EID: 2-s2.0-85060957451

Source: Scopus – Elsevier