Farid Taghinavaz | Quark Matter Phase Transition | Best Researcher Award

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Dr. Farid Taghinavaz | Quark Matter Phase Transition | Best Researcher Award 

Researcher, at IPM, Iran.

Farid Taghinavaz, Ph.D., is a Senior Postdoctoral Research Fellow at the School of Particles and Accelerators, Institute for Research in Fundamental Sciences (IPM), Tehran, Iran. With expertise in particle physics and thermal field theory, Dr. Taghinavaz has made significant contributions to the understanding of heavy-ion collisions and quark-gluon plasma dynamics. He has held multiple academic positions at IPM since 2016 and is a prolific researcher with numerous peer-reviewed publications. Dr. Taghinavaz is also an active member of the Physics Society of Iran (PSI) and has organized international workshops on QGP phenomenology.

Professional Profile

Scopus

Google Scholar

ORCID

Education 📘

  • Ph.D. in Particle Physics (2012-2017): Sharif University of Technology, Tehran, Iran
    Graduated with a 19.75/20 GPA. Dissertation: “On the effects of finite temperature and background magnetic fields on heavy-ion collision observables.”
  • M.Sc. in Particle Physics (2010-2012): Sharif University of Technology, Tehran, Iran
    Graduated with a 19.2/20 GPA. Dissertation: “Magnetic Susceptibility of quark matter in non-homogeneous fields.”
  • B.Sc. in Physics (2006-2010): Tehran University, Iran
    Graduated with a 18.2/20 GPA, ranking 1st in the department.

Experience 🏛️

  • Senior Postdoctoral Research Fellow (2022–Present): School of Particles and Accelerators, IPM.
  • Resident Researcher (2019–2022): School of Particles and Accelerators, IPM.
  • Postdoctoral Research Fellow (2016–2019): School of Particles and Accelerators, IPM.

Dr. Taghinavaz has also served as a lecturer and research advisor, teaching advanced topics such as quantum field theory and analytical mechanics.

Research Interests 🔬

Dr. Taghinavaz’s research spans:

  • Phase transitions in quark matter.
  • Relativistic hydrodynamics and dynamical QCD properties.
  • Thermal field theory in heavy-ion collisions.

His work focuses on studying the behaviors of quark-gluon plasma under extreme conditions, leveraging computational techniques to advance theoretical models.

Awards and Honors 🏆

  • Grant from National Talented Organization of Iran (2014).
  • 1st Rank in the Physics Department, Tehran University (2010).
  • 5th Rank in the National Physics Olympiad for University Students (2009).
  • Member of the Physics Society of Iran (since 2017).

Publications 📑

  • Taghinavaz, F. & Torrieri, G.
    Linearized fluctuating hydrodynamics via random polynomials,
    Phys. Rev. D, 110(5), 056019 (2024).
    Cited by: 8 articles.
    View publication
  • Heydari, R., & Taghinavaz, F.
    Local univalence versus stability in hydrodynamic models,
    Eur. Phys. J. C (EPJC), Accepted for publication (2024).
    Cited by: 5 articles.
    View publication
  • Daher, A., Florkowski, W., Ryblewski, R., & Taghinavaz, F.
    Second-order spin hydrodynamics,
    Phys. Rev. D, 109(11), 114001 (2024).
    Cited by: Information pending.
    View publication

Conclusion

Farid Taghinavaz is a distinguished researcher with a strong record of academic achievement, impactful research, and dedicated teaching and community service. His expertise in particle physics, coupled with significant contributions to hydrodynamics and quark-gluon plasma phenomenology, make him a strong candidate for the Best Researcher Award. With minor efforts to diversify his collaborations and increase public engagement, his profile would be further strengthened for future accolades.

 

Evgeny Liverts | Atomic Physics | Best Researcher Award

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Dr. Evgeny Liverts | Atomic Physics | Best Researcher Award

Dr. Evgeny Liverts Racah, Institute of Physics. The Hebrew University of Jerusalem, Israel

Dr. Evgeny Liverts is a theoretical physicist and senior researcher at the Racah Institute of Physics, Hebrew University of Jerusalem, Israel. With a Ph.D. in Physics from the Institute of Nuclear Physics, Alma-Ata, he has made significant contributions to computational quantum mechanics, atomic physics, and nuclear physics. His expertise spans advanced computational methods, ab initio calculations, and the study of atomic and molecular systems. Dr. Liverts has over four decades of experience in research, including a strong background in theoretical aspects of the Mössbauer effect and high-temperature superconductivity.

PROFILE

Orcid  Profile

Educational Detail

Master’s Degree (1974): Department of Theoretical Physics, Faculty of Physics, Dnepropetrovsk State University, USSR.

Ph.D. Degree (1983): Institute of Nuclear Physics, Alma-Ata, USSR. Approved by the Higher Attestation Commission, USSR Council of Ministers, Moscow (1983) and the Israeli Ministry of Education, Jerusalem (2005).

Professional Experience

Senior Scientist (1991–2002): Institute of Nuclear Physics, Alma-Ata, Kazakhstan.

Scientist (1983–1990): Institute of Nuclear Physics, Alma-Ata, Kazakhstan.

Junior Scientist (1977–1982): Institute of Nuclear Physics, Alma-Ata, Kazakhstan.

Engineer (1975–1976): Institute of Nuclear Physics, Alma-Ata, Kazakhstan.

Current Role: Researcher at the Racah Institute of Physics, Hebrew University of Jerusalem, Israel.

Research Interests

Dr. Liverts is an accomplished physicist with expertise in theoretical physics and quantum mechanics. His primary research directions include:

Development of advanced computational methods, including the Correlation Function Hyperspherical Harmonic Method (CFHHM) and quasilinearization techniques for solving Schrödinger’s equation.

Study of atomic systems, including double photoionization of atoms encapsulated in fullerenes and specific configurations of two-electron systems.

Ab initio calculations of atomic, nuclear, and molecular systems, focusing on non-relativistic energies, wave functions, and electroweak cross-sections in light nuclear systems.

Refinement of angular Fock coefficients, atomic coalescences, and calculations of bound and quasi-bound states in multi-body systems.

Theoretical studies of the Mössbauer effect and high-temperature superconductors using modern quantum chemistry techniques.

Skills

Proficient in Fortran (77, 90) and Wolfram Mathematica.

Experienced with operating systems such as Windows, Unix, and Linux.

Reviewer for leading scientific journals, including Physica Scripta, Journal of Physics A, Annals of Physics, and Computational Physics Communications.

Top Notable Publications

Evgeny Liverts (2024). “Two-Electron Atomic Systems—A Simple Method for Calculating the Ground State near the Nucleus: Some Applications.” Atoms, DOI: 10.3390/atoms12120069.

Evgeny Liverts (2022). “Fock Expansion for Two-Electron Atoms: High-Order Angular Coefficients.” Atoms, DOI: 10.3390/atoms10040135.

Evgeny Liverts (2022). “Co-spherical Electronic Configuration of the Helium-Like Atomic Systems.” Annals of Physics, DOI: 10.1016/j.aop.2021.168669.

Evgeny Liverts (2021). “Accurate Exponential Representations for the Ground State Wave Functions of the Collinear Two-Electron Atomic Systems.” Atoms, DOI: 10.3390/atoms10010004.

Evgeny Liverts (2020). “Collinear Configuration of the Helium Atom and Two-Electron Ions.” Annals of Physics, DOI: 10.1016/j.aop.2020.168306.

Evgeny Liverts (2020). “Averaged Electron Densities of the Helium-Like Atomic Systems.” Journal of Mathematical Physics, DOI: 10.1063/1.5129026.

Evgeny Liverts (2018). “The Green’s Function Approach to the Fock Expansion Calculations of Two-Electron Atoms.” Journal of Physics A: Mathematical and Theoretical, DOI: 10.1088/1751-8121/aaa2ce.

Conclusion

Dr. Evgeny Liverts is an exemplary candidate for the Research for Best Researcher Award due to his extensive contributions to theoretical physics, computational methods, and atomic studies. His innovative research, supported by a solid academic foundation and decades of professional expertise, makes him a strong contender for this prestigious recognition.

 

 

 

 

 

 

 

 

 

 

 

 

Muhammad Sajid | Quantum Science | Best Researcher Award

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Dr. Muhammad Sajid | Quantum Science | Best Researcher Award

Orcid Profile

Scopus Profile

Educational Details:

Dr. Muhammad Sajid is a physicist with expertise in quantum simulations, condensed matter physics, and quantum information. He earned his Ph.D. in Physics (Magna cum Laude) from Bonn University, Germany, in 2018, under the supervision of Professor Dieter Meschede and Dr. Andrea Alberti. His thesis focused on the “Magnetic Quantum Walks of Neutral Atoms in Optical Lattices.” Prior to his doctoral studies, Dr. Sajid completed an M.Phil. in Physics in 2012 at Quaid-i-Azam University, Islamabad, where he studied the behavior of Bose-Einstein Condensates under Gaussian random potentials. He also holds an M.Sc. in Physics (2010) from the same institution, where he was awarded the Chancellor Medal, and a B.Sc. with Distinction from the University of Peshawar (2007). His academic journey began with a distinguished performance during his F.Sc. Pre-Engineering studies in 2005 and matriculation in 2003, both completed with distinctions in Peshawar.

Professional Experience

Professionally, Dr. Sajid has been a Postdoctoral Researcher at the Institute of Fundamental and Frontier Sciences, University of Electronic Science and Technology of China (UESTC), since December 2023. Before that, he served as an Assistant Professor in Physics at Kohat University of Science and Technology, Pakistan, from February 2018 to December 2023, and as a Lecturer in Physics at the same institution from December 2010 to February 2018. His academic roles have involved both teaching and research, with a focus on advancing the understanding of quantum systems.

Research Interest

Dr. Sajid’s research interests encompass a broad range of topics within quantum physics. He is particularly interested in Quantum Walks, Quantum Simulations with Quantum Walks, Condensed Matter Physics, Quantum Information and Computation, Topological Phenomena in Driven Quantum Systems, Bose-Einstein Condensates, and Many-Body Localization. His work delves into both theoretical and experimental aspects of these phenomena, contributing to the advancement of knowledge in quantum systems and their potential applications.

Top Notable Publications

Sajid, M., Khan, N.A., & Shah, M. (2024). Topological pumping in an inhomogeneous Aubry–André model. Chinese Journal of Physics, 92, 311–320.
Citations: 0

Shah, M., Shah, M., Khan, N.A., Abo-Dief, H.M., & Alzahrani, E. (2024). Spin and valley-polarized Faraday rotation in irradiated buckled Xene materials. Optical Materials Express, 14(7), 1676–1689.
Citations: 1

Shah, M., Shah, M., Khan, N.A., Jan, M., & Xianlong, G. (2024). Tunable quantized spin Hall effect of light in graphene. Results in Physics, 60, 107676.
Citations: 2

Shah, M., Hayat, A., Sajid, M., Khan, N.A., & Jan, M. (2023). Photonic spin Hall effect in uniaxially strained graphene. Physica Scripta, 98(12), 125943.
Citations: 3

Sajid, M., Shah, M., Khan, N.A., & Jan, M. (2023). Quantum walks in an inhomogeneous off-diagonal Aubry-André-Harper model. Physics Letters A, 469, 128763.
Citations: 1

Shah, M., Khan, N.A., & Sajid, M. (2022). Optical conductivity of ultrathin Floquet topological insulators. Journal of Physics D: Applied Physics, 55(41), 415103.
Citations: 1

Khan, N.A., Muhammad, S., Sajid, M., & Saud, S. (2022). Single parameter scaling in the non-Hermitian Anderson model. Physica Scripta, 97(7), 075817.
Citations: 0

Khan, N.A., Jan, M., Shah, M., Ali, M., & Khan, D. (2022). Entanglement-based measure of non-Makovianity in relativistic frame. Optik, 260, 169016.
Citations: 0

Khan, N.A., Muhammad, S., & Sajid, M. (2022). Single parameter scaling in the correlated Anderson model. Physica E: Low-Dimensional Systems and Nanostructures, 139, 115150.
Citations: 6

Conclusion

Dr. Muhammad Sajid’s extensive experience in quantum simulations, condensed matter physics, and Bose-Einstein Condensates, along with his impressive educational achievements and teaching career, make him a highly suitable candidate for the Best Researcher Award. His contributions to quantum physics demonstrate both depth and innovation, positioning him as a leader in his field.

 

Adrian Cheok | Quantum Physics | Best Researcher Award

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Prof Dr. Adrian Cheok | Quantum Physics | Best Researcher Award

Prof Dr. Adrian Cheok, Nanjing University of Information Science and Technology,  Australia

Adrian David Cheok AM is a distinguished researcher and academic specializing in mixed reality and human-computer interaction. With a robust background in engineering and extensive experience across international institutions, Cheok leads pioneering work in wearable computing and mixed reality. He has received numerous accolades, including Australia’s highest honor, the Order of Australia, for his significant contributions to global research and education. His innovative work, recognized globally, continues to impact and advance the fields of technology and interactive media.

PROFILE

Scopus Profile

Orcid Profile

Educational Details

Adrian David Cheok AM, born and raised in Adelaide, Australia, has a distinguished educational background. He earned his Bachelor of Engineering (Electrical and Electronic) with First Class Honours from the University of Adelaide in 1993. He continued his studies at the same institution, obtaining a Ph.D. in Electrical and Electronic Engineering in 1998. In addition to his engineering qualifications, Cheok pursued a Graduate Diploma in Global Leadership and Public Policy for the 21st Century from Harvard University in 2010. This diverse academic foundation underpins his extensive career in research and leadership in technology and innovation.

Professional Experience:

Adrian David Cheok is a prominent figure in the fields of mixed reality and human-computer interaction. He is the Director of the Imagineering Institute in Malaysia and holds multiple academic positions, including Full Professor at i-University Tokyo, Visiting Professor at Raffles University Malaysia and the University of Novi Sad, Serbia. Additionally, he serves on the Technical Faculty at “Mihailo Pupin” in Serbia and Ducere Business School, and is the CEO of Nikola Tesla Technologies Corporation.

Previously, Cheok was Professor of Pervasive Computing at the University of London, Full Professor and Executive Dean at Keio University’s Graduate School of Media Design, and Associate Professor at the National University of Singapore. He has also worked at Mitsubishi Electric Research Labs in Japan focusing on real-time systems, soft computing, and embedded computing.

Research Interest

Cheok’s research encompasses mixed reality, human-computer interfaces, wearable computers, and ubiquitous computing. His work also spans fuzzy systems, embedded systems, and power electronics. He has successfully secured approximately $130 million in funding for projects from notable organizations such as the Daiwa Foundation, Khazanah National, and various government and private entities. His innovative research has been featured in high-profile media outlets, international exhibitions, and has garnered numerous awards and recognitions, including the Order of Australia in 2019 for his contributions to international education and research.

Research Goals

Adrian David Cheok AM reflects on the transformative impact of interactive media, emphasizing its role in revolutionizing communication and human-computer interaction. He draws inspiration from pioneers like Douglas Engelbart and Alan Kay, advocating for a multidisciplinary approach to research that blends imaginative envisioning, future-casting, and creative engineering. Cheok’s passion lies in pushing the boundaries of interactive media to create innovative technologies that enhance communication, learning, and entertainment. His goal is to drive impactful, cutting-edge research that benefits society and inspires future generations of researchers.

Top Notable Publications

On the Same Origin of Quantum Physics and General Relativity from Riemannian Geometry and Planck Scale Formalism

Journal: Astroparticle Physics

Year: 2025

DOI: 10.1016/j.astropartphys.2024.103036

Optimal Design and Control of a Decoupled Multifrequency Multiphase Wireless Switched Reluctance Motor Drive System

Journal: IEEE Transactions on Power Electronics

Year: 2024

DOI: 10.1109/TPEL.2024.3399737

Magnetic Coupled Wireless Motor Driving Systems–An Overview

Journal: IEEE Transactions on Power Electronics

Year: 2024

DOI: 10.1109/TPEL.2024.3372312

The Convergence of Traditionalism and Populism in American Politics

Book: IGI Global

Year: 2024

DOI: 10.4018/978-1-6684-9290-1

Unraveling Populism: Senator Fraser Anning and the Australian Political Landscape

Preprint

Year: 2024

DOI: 10.32388/L3ED9I

A Soft Decoding Strategy For The Resolver in Motor Drive System

Journal: IEEE Transactions on Transportation Electrification

Year: 2024

DOI: 10.1109/TTE.2024.3415433

Flux-Linkage Loop-Based Model Predictive Torque Control for Switched Reluctance Motor

Journal: IEEE Transactions on Industrial Electronics

Year: 2024

DOI: 10.1109/TIE.2024.3443955

Model Predictive Control Strategies in Switched Reluctance Motor Drives – An Overview

Journal: IEEE Transactions on Power Electronics

Year: 2024

DOI: 10.1109/TPEL.2024.3454819

Overview of the Direct Torque Control Strategy in Switched Reluctance Motor Drives

Journal: IEEE Transactions on Transportation Electrification

Year: 2024

DOI: 10.1109/TTE.2024.3408647

From Turing to Transformers: A Comprehensive Review and Tutorial on the Evolution and Applications of Generative Transformer Models

Journal: Sci

Year: 2023

DOI: 10.3390/sci5040046