Dr. Nan Liu | Physics | Best Researcher Award

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Dr. Nan Liu | Physics | Best Researcher Award

Student at University of Science and Technology Beijing, China

Dr. Nan Liu 🎓 is a rising scholar in the domain of mechanics, renowned for her cross-disciplinary grasp of mathematics, physics, and materials science. With an ongoing Ph.D. at the University of Science and Technology Beijing 🏛️, she delves into the intricate world of crystal nucleus growth during solidification — a pivotal concept in materials engineering. Her analytical mindset 🌐 was shaped early on during her Master’s in Applied Mathematics and a Bachelor’s in Mathematics and Applied Math. Backed by national-level funding 💰 from the NSFC, her research is crucial to understanding the kinetics of nanosecond phase formation in copper alloys. With a methodical approach and a passion for deep theoretical exploration, Nan Liu’s academic arc reflects both precision and persistence. She symbolizes the future of multidisciplinary scientific investigation 🔍, standing at the intersection of abstract modeling and material behavior. Her journey is as structured as the crystals she studies — ordered, impactful, and evolving. ✨

Professional Profile 

📘 Education

Nan Liu’s 📚 academic odyssey is rooted in rigorous disciplines and thoughtful progression. She is currently pursuing a Ph.D. in General and Fundamental Mechanics at the University of Science and Technology Beijing (2020–2025), under the mentorship of Prof. Ming-Wen Chen 🧪. Her doctoral thesis focuses on crystal nucleus growth morphology — a vital concern in solidification science. Earlier, she earned a Master’s degree in Applied Mathematics (2016–2019) from Beijing Information Science & Technology University, exploring dynamic behaviors of nonlinear equations 🌀 under the guidance of Prof. Xiao-Yong Wen. Her journey began with a Bachelor’s in Mathematics and Applied Mathematics from Baotou Teachers’ College (2012–2016), where she built the foundational knowledge that now underpins her interdisciplinary insight. Each academic stage not only honed her technical acumen but also broadened her lens toward complex problem-solving and real-world modeling 🔭 — making her a well-rounded, resilient, and intellectually curious researcher. 🎓✨

💼 Professional Experience

Though primarily rooted in academia, Nan Liu’s professional development 🌐 reflects deep immersion in research-intensive environments. As a doctoral candidate, she actively engages in computational modeling, thermophysical analysis, and solidification dynamics — collaborating with peers and mentors in high-precision labs 🔬. Her participation in funded research under the NSFC grant has given her project management experience, proficiency in analytical tools, and exposure to multi-phase material behavior under shear flows ⚙️. While her CV does not yet reflect formal industry roles, her academic trajectory mimics a research scientist’s responsibilities: hypothesis formulation, numerical simulation, data interpretation, and scholarly dissemination 📈. She contributes to the academic community by assisting in coursework, guiding junior students, and participating in departmental research seminars. Nan Liu’s role as a scholar is more than theoretical; it is a living practice of scientific exploration and knowledge transfer. With this blend of technical depth and project involvement, she is poised for impactful contributions to science and engineering. 🧑‍🔬📊

🔬 Research Interests

Nan Liu’s research world 🌍 orbits around the intersections of mathematics, physics, and materials science — forming a triad of intellectual synergy. Her core focus is the solidification processes in metallic systems, especially the morphology of crystal nuclei during rapid phase transformations. She explores how nanosecond-scale phase formations are influenced by multidimensional shear flows, utilizing a blend of kinetic theory, dynamic systems, and thermodynamic modeling 🔥. Her background in nonlinear equations and applied mathematics enables her to investigate material behaviors through both numerical and analytical lenses 📐. Beyond materials science, she maintains a deep interest in theoretical physics and computational simulations — seeking universal patterns and predictive models within complex systems. Her vision is to bridge the gap between abstract theory and real-world materials engineering 🧩, pushing the boundaries of how we understand the microstructural evolution in advanced alloys. With curiosity and rigor, she forges knowledge at the edge of known science. 🚀

🏆 Awards and Honors

Nan Liu’s academic journey 🌟 has been highlighted by her participation in a prestigious NSFC-funded research project (Grant No. 51971031), focusing on in-situ phase formation during alloy solidification — a competitive and nationally significant initiative 💼. While explicit awards aren’t listed, being entrusted with such a cutting-edge project testifies to her scientific credibility, diligence, and intellectual promise 🧠. Her consistent academic excellence across undergraduate, graduate, and doctoral levels — in elite institutions such as USTB — reflects the high standards she has upheld throughout her career. She has also gained recognition within her research groups for problem-solving, modeling proficiency, and collaborative mindset 🤝. Whether presenting her findings in internal forums or contributing to experimental validations, Nan Liu remains a trusted and respected member of her academic community. These honors may not always be in the form of medals 🥇, but they are etched into the foundations of impactful research and scholarly trust. 🎓🔬

📚 Publications Top Note 

Title: A Particle-Based Approach for the Prediction of Grain Microstructures in Solidification Processes

Authors: Salem Mosbah, Rodrigo Gómez Vázquez, Constantin Zenz, Damien Tourret, Andreas Otto

Published: April 17, 2025

DOI: 10.48550/arXiv.2504.12858

Summary:
This study introduces a novel approach to track crystallographic solidification grain envelopes using Lagrangian particles. The model simulates competitive grain growth scenarios and transitions between columnar and equiaxed structures. It has been validated against analytical, experimental, and numerical results, and coupled with a laser-material-interaction model to simulate grain growth during laser beam welding of steel.

🧩 Conclusion

Nan Liu is not merely a scholar 📖 — she is an embodiment of cross-disciplinary excellence, threading together mathematics, physics, and materials science into a unified quest for understanding the building blocks of matter 🔍. With strong roots in theory and hands-on application, her research is both groundbreaking and relevant, contributing to material design, thermophysical modeling, and solidification dynamics. She is supported by national funding and shaped by elite mentorship — a clear sign of her standing in the academic arena 🏛️. Her trajectory suggests not just potential but a strong certainty of impact in the field of mechanics and beyond. Whether pursuing postdoctoral endeavors, teaching, or continuing in high-level research, Nan Liu is poised to become a significant contributor to science’s future. Her journey is one of precision, patience, and purposeful curiosity 🌌 — and her story is just beginning to unfold. 🌱🔮

Prof. Raoelina Andriambololona | Physics | Best Researcher Award

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Prof. Raoelina Andriambololona | Physics | Best Researcher Award

Emeritus Professor at Institut National des Sciences et Techniques Nucléaires, Madagascar

Prof. Raoelina Andriambololona 🇲🇬 is an iconic figure in the global scientific community, renowned for his pioneering contributions to nuclear physics, theoretical science, and sustainable development. With over six decades of dedicated service, he has transformed science and technology education in Madagascar and across Africa. From being a CNRS researcher in France to establishing world-class research institutions back home, Prof. Raoelina’s vision is deeply rooted in innovation, self-reliance, and scientific ethics. A prolific author of 250+ publications 📚 and several university-level books, he continues to inspire generations of physicists. His leadership in nanotechnology, environmental protection, and science diplomacy has earned him numerous global honors 🏅. Fluent in Malagasy, French, and English, and with professional footprints in over 30 countries, Prof. Raoelina stands as a beacon of excellence, dedication, and intellectual humility. His legacy is not only academic but deeply humanistic 🌱💡.

Professional Profile 

🎓 Education

Prof. Raoelina’s academic odyssey began in Madagascar and blossomed at the University of Aix-Marseille, France 🇫🇷, where he obtained his Doctorat ès Sciences d’État in 1967. His earlier credentials include a Doctorate of 3rd Cycle in Theoretical Physics (1962), diplomas in pure and applied mathematics (1957–1958), and a degree in physical sciences. This rich foundation empowered his intellectual pursuit across quantum theory, linear algebra, and advanced mechanics 🧠📘. His education wasn’t just confined to acquiring degrees but focused on laying the groundwork for a national educational revolution in Madagascar. The blend of French scientific rigor and Malagasy passion shaped him into a transcontinental academic luminary. His multilingual fluency in Malagasy, French, and English further cemented his ability to bridge knowledge between diverse cultures 🌐🗣️. His journey embodies a harmonious union of deep theoretical insight and practical academic engineering.

🧪 Professional Experience

Prof. Raoelina’s professional career radiates across continents and sectors, beginning as a researcher at CNRS–Marseille in the 1960s and later as Professor Titulaire in Madagascar by 1972 🧑‍🏫. He was instrumental in founding multiple institutions from scratch, including the Laboratoire de Physique Nucléaire and the Institut National des Sciences et Techniques Nucléaires (INSTN). Nationally, he shaped physics education, built observatories, and opened the first graduate programs in nuclear physics. Internationally, he served as an advisor to the UNDP, IAEA liaison officer for decades, Fulbright professor in the U.S., and UNESCO expert advisor 🌍🔬. His role as Scientific Advisor to the President of Madagascar (1986–1991) further reflects his unique ability to integrate science with policy and national development. Raoelina is not only a pioneer in academia but a strategist in science infrastructure development, capacity building, and global knowledge networks 🧭🏗️.

🔬 Research Interests

Prof. Raoelina’s research traverses a remarkable spectrum—ranging from particle physics, quantum mechanics, and nuclear spectroscopy to nanotechnology, fractional calculus, and environmental science. His scientific curiosity has been deeply interdisciplinary, focusing also on linear and multilinear algebra, development studies, and ethics in science 🧠🌿. His commitment to applied research is evident in his work on X-ray fluorescence for ore analysis, radiation protection, and environmental monitoring. With a sharp lens on the challenges of developing countries, he emphasizes indigenous knowledge, sustainability, and technology transfer 📈. His vision of endogenous development and the use of native language in science education marks him as both a thought leader and cultural reformist. His 250+ publications are not just academic outputs but serve as knowledge vehicles across generations and geographies. Prof. Raoelina’s research transcends the lab—blending intellect with societal impact 🎯📖.

🏆 Awards and Honors

Prof. Raoelina’s excellence has been globally acknowledged through numerous prestigious honors 🌟. He is the 2020 recipient of the TWAS-C.N.R. Rao Award for Scientific Research and holds national decorations such as the Grand-Croix de 2ème classe de l’Ordre National Malagasy (1997) and Commandeur de l’Ordre du Mérite de Madagascar (1991). These awards recognize not only his scholarly brilliance but also his unwavering dedication to national science development. His election to the African Academy of Sciences, TWAS, and the New York Academy of Sciences confirms his impact on the international stage 🌐. As the founding president of several national scientific societies and advisory boards, his role as a scientific statesman is undeniable. Through music, ethics, and education, his contributions have extended beyond the lab and lecture hall. These accolades are testaments to a life passionately lived in service of knowledge and humanity 🕊️📜.

📚 Publications Top Note 

1.Title: Assessment of soil redistribution rates by 137Cs and 210Pbex in a typical Malagasy agricultural field
Authors: N Rabesiranana, M Rasolonirina, AF Solonjara, HN Ravoson, …
Year: 2016
Citations: 32
Source: Journal of Environmental Radioactivity, Volume 152, Pages 112-118
Summary:
This study investigates soil erosion and redistribution rates in agricultural fields of Madagascar using radioactive tracers 137Cs and 210Pbex. These isotopes serve as markers to quantify soil movement and deposition, offering insights into land degradation processes in typical Malagasy agricultural settings.

2.Title: Algèbre linéaire et multilinéaire
Author: R Andriambololona
Year: 1986
Citations: 28
Source: Applications, Collection LIRA, INSTN Madagascar
Summary:
A comprehensive treatise on linear and multilinear algebra, focusing on theoretical foundations and applications. It is a foundational text for mathematical education and research in Madagascar, especially in algebraic structures relevant to physics and engineering.

3.Title: Top soil radioactivity assessment in a high natural radiation background area: The case of Vinaninkarena, Antsirabe—Madagascar
Authors: N Rabesiranana, M Rasolonirina, F Terina, AF Solonjara, …
Year: 2008
Citations: 24
Source: Applied Radiation and Isotopes, Volume 66, Issue 11, Pages 1619-1622
Summary:
This paper assesses the natural radioactivity levels in the topsoil of Vinaninkarena, an area with high natural radiation background in Madagascar. The findings provide important baseline data for environmental radiation monitoring and public health considerations.

4.Title: Dispersion Operators Algebra and Linear Canonical Transformations
Authors: R Andriambololona, RT Ranaivoson, R Hasimbola Damo Emile, …
Year: 2017
Citations: 22
Source: International Journal of Theoretical Physics, Volume 56, Issue 4, Pages 1258-1273
Summary:
This article presents a theoretical framework linking dispersion operators algebra with linear canonical transformations, important in mathematical physics and quantum mechanics. It advances the understanding of operator theory in quantum contexts.

5.Title: Study on a phase space representation of quantum theory
Authors: T Ranaivoson, R Andriambololona, R Hanitriarivo, R Raboanary
Year: 2013
Citations: 21
Source: arXiv preprint arXiv:1304.1034
Summary:
The paper explores phase space formulations of quantum mechanics, offering novel insights into representing quantum states and operators. It emphasizes the theoretical and computational advantages of this approach.

6.Title: Cleft lip and palate in Madagascar 1998–2007
Authors: RA Rakotoarison, AE Rakotoarivony, N Rabesandratana, …
Year: 2012
Citations: 20
Source: British Journal of Oral and Maxillofacial Surgery, Volume 50, Issue 5, Pages 430-434
Summary:
An epidemiological study documenting the incidence, treatment, and outcomes of cleft lip and palate cases in Madagascar over a decade. The research highlights healthcare challenges and the need for improved surgical interventions.

7.Title: Definitions of real order integrals and derivatives using operator approach
Author: R Andriambololona
Year: 2012
Citations: 20
Source: arXiv preprint arXiv:1207.0409
Summary:
This paper introduces an operator-based method to define fractional calculus concepts such as real order integrals and derivatives, contributing to the mathematical theory with potential applications in physics and engineering.

8.Title: Linear canonical transformations in relativistic quantum physics
Authors: RT Ranaivoson, R Andriambololona, H Rakotoson, R Raboanary
Year: 2021
Citations: 17
Source: Physica Scripta, Volume 96, Issue 6, 065204
Summary:
The authors analyze the role of linear canonical transformations in the framework of relativistic quantum physics, exploring their implications for the symmetry and dynamics of quantum systems.

9.Title: A study of the Dirac-Sidharth equation
Authors: R Andriambololona, C Rakotonirina
Year: 2009
Citations: 16
Source: arXiv preprint arXiv:0910.2868
Summary:
The paper investigates the Dirac-Sidharth equation, a modification of the Dirac equation in quantum mechanics, focusing on its mathematical properties and physical interpretations.

10.Title: Time-Frequency analysis and harmonic Gaussian functions
Authors: T Ranaivoson, R Andriambololona, R Hanitriarivo
Year: 2013
Citations: 15
Source: arXiv preprint arXiv:1303.1909
Summary:
This research develops methods for time-frequency analysis using harmonic Gaussian functions, relevant for signal processing and quantum mechanics.

11.Title: Mécanique quantique
Author: R Andriambololona
Year: 1990
Citations: 15
Source: Collection LIRA, INSTN Madagascar, pp. 25.387-394
Summary:
A foundational book on quantum mechanics, covering theoretical concepts, mathematical formalism, and applications. It serves as a key reference for students and researchers in Madagascar.

🧭 Conclusion

Prof. Raoelina Andriambololona is not merely a scientist—he is a visionary builder of nations through science 🌍🏛️. His unparalleled contributions in education, research, and policy over six decades mark him as a towering intellectual of Africa and the global South. With a career rooted in humility, foresight, and innovation, he has redefined what it means to be a scientist in service of humanity. His legacy is cemented in institutions, publications, and minds that continue to carry forward his mission 💡📚. Whether in physics, ethics, development, or music, Prof. Raoelina remains a multifaceted scholar and cultural pillar. His work exemplifies the role of science in shaping just, informed, and sustainable societies. As future generations draw inspiration from his life’s work, his name shall endure in the annals of both scientific discovery and national empowerment 🌟🧬.

Keumo Tsiaze Roger Magloire | Physics | Best Researcher Award

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Dr. Keumo Tsiaze Roger Magloire | Physics | Best Researcher Award

Dr. Keumo Tsiaze Roger Magloire at University of Yaoundé I, Cameroon

Dr.Keumo Tsiaze Roger Magloire is a dynamic and passionate physicist 🎓, blending solid academic roots with hands-on research and pedagogical experience. Holding a Master’s, Bachelor’s, and a Teaching Diploma in Physics from the University of Yaoundé I 🇨🇲, he has demonstrated flexibility, innovation, and team spirit throughout his academic and professional journey. Currently serving as an Associate Researcher at the prestigious ICMPA-UNESCO Chair in Benin 🇧🇯, he excels in theoretical and computational physics, with interests in quantum information theory and the structure-property relationship of novel materials. Proficient in LaTeX, MATLAB, and Maple 💻, he balances his scientific rigor with humanitarian activities and sports ⚽🏐. His multilingual skills (native in French, C1 in English) add to his global research engagement 🌍. Driven by curiosity and commitment, Dr. KEUMO contributes meaningfully to cutting-edge research projects in superconductivity, magnetism, and nanostructures.

Professional Profile 

Orcid

Google Scholar

🎓 Education

Dr. Keumo’s academic foundation is rooted in excellence. He earned his Bachelor’s and Master’s degrees in Physics, along with a Second Grade Teaching Diploma, from the University of Yaoundé I 🏛️. This blend of scientific and pedagogical training empowers him with both technical depth and classroom agility. His education cultivated a strong understanding of mechanics, materials, and structural behavior under diverse conditions 🧪. The teaching diploma gave him a professional edge in delivering complex concepts clearly and effectively 🗣️. Dr. KEUMO’s educational journey reflects resilience, curiosity, and dedication to learning, which he continues to apply in his research and teaching. His capacity to work across academic disciplines is a reflection of the comprehensive scientific preparation he received during his formative academic years.

💼 Professional Experience

Currently, Dr. Keumo holds a distinguished position as Associate Researcher at the International Chair of Mathematical Physics and Applications (ICMPA-UNESCO) in Cotonou, Benin 🌐. His role involves advanced theoretical investigations into quantum materials and superconducting phenomena. With strong computational skills in LaTeX, MATLAB, and Maple, he effectively navigates complex modeling and simulations ⚙️. His earlier experience at the University of Yaoundé I included laboratory research in mechanics and material sciences, where he honed his adaptability and team collaboration skills. Known for his creative and critical thinking, he consistently demonstrates the ability to engage with multidisciplinary challenges. The teaching dimension of his profile, grounded in a second-grade diploma, gives him a unique pedagogical strength 📚, allowing him to contribute effectively in both research and academic mentoring environments.

🔬 Research Interests

Dr. Keumo’s research landscape is vast and profound 🌌. He explores structure-property relationships in novel materials, emphasizing their behavior in complex environments. His work in quantum information theory delves into the heart of modern physics, pushing boundaries in areas like quantum dots and superconducting qubits. His current projects focus on superconducting ferromagnets, tunneling wire qubits, and two-dimensional TMDCs (like MoS₂, WS₂) used in Josephson junction laser systems ⚡. He is deeply invested in understanding multiferroic systems, exchange interactions, and size effects in amorphous magnetic materials. Dr. KEUMO’s theoretical models aim to predict new phenomena and aid technological advancements in quantum computing and nanoscale magnetism 💡. His interdisciplinary vision positions him at the intersection of theoretical physics and material science, making his research both futuristic and applicable.

🏅 Awards and Honors

Though specific awards are not listed, Dr. Keumo’s esteemed roles and affiliations speak volumes 🌟. Being appointed an Associate Researcher at ICMPA-UNESCO Chair is itself a testament to his scholarly merit and recognition in the international physics community. His achievements in teaching and research demonstrate a blend of academic honor and societal contribution. His pedagogical credentials, coupled with his involvement in humanitarian outreach, reflect a commitment to uplifting others through knowledge and service 🙌. His bilingual abilities in French and English 🗨️ also enhance his global academic engagement. The respect he commands in both francophone and anglophone research circles adds a multicultural dimension to his scholarly persona.

📚 Publications Top Note 

1. The intensity and direction of the electric field effects on off-center shallow-donor impurity binding energy in wedge-shaped cylindrical quantum dots

  • Authors: L. Belamkadem, O. Mommadi, R. Boussetta, S. Chouef, M. Chnafi, …

  • Year: 2022

  • Citations: 31

  • Source: Thin Solid Films, Vol. 757, 139396

  • Summary: Investigates how varying the intensity and direction of electric fields alters the binding energy of off-center shallow donor impurities in wedge-shaped cylindrical quantum dots. It reveals key insights into impurity localization and tunability of electronic properties in nanostructures.

2. Tunable potentials and decoherence effect on polaron in nanostructures

  • Authors: A.J. Fotue, M.F.C. Fobasso, S.C. Kenfack, M. Tiotsop, J.R.D. Djomou, …

  • Year: 2016

  • Citations: 29

  • Source: The European Physical Journal Plus, Vol. 131, 1–15

  • Summary: Explores how tunable potential wells and decoherence mechanisms affect polarons in quantum dots and other nanostructures. It provides theoretical frameworks to understand energy loss and coherence in nanomaterials.

3. Deformation and size effects on electronic properties of toroidal quantum dot in the presence of an off-center donor atom

  • Authors: R. Boussetta, O. Mommadi, L. Belamkadem, S. Chouef, M. Hbibi, …

  • Year: 2022

  • Citations: 26

  • Source: Micro and Nanostructures, Vol. 165, 207209

  • Summary: Analyzes how geometric deformations and scaling influence the electronic structure of toroidal quantum dots with embedded donor atoms. Provides guidance for quantum device engineering at nanoscale dimensions.

4. Renormalized Gaussian approach to critical fluctuations in the Landau–Ginzburg–Wilson model and finite-size scaling

  • Authors: R.M.K. Tsiaze, S.E.M. Tchouobiap, J.E. Danga, S. Domngang, …

  • Year: 2011

  • Citations: 12

  • Source: Journal of Physics A: Mathematical and Theoretical, Vol. 44 (28), 285002

  • Summary: Develops a renormalized Gaussian approximation to analyze critical fluctuations and finite-size effects in systems governed by the Landau-Ginzburg-Wilson model. Useful in studying phase transitions in condensed matter.

5. Thermodynamic properties of a monolayer transition metal dichalcogenide (TMD) quantum dot in the presence of magnetic field

  • Authors: T.V. Diffo, A.J. Fotue, S.C. Kenfack, R.M.K. Tsiaze, E. Baloitcha, …

  • Year: 2021

  • Citations: 11

  • Source: Physics Letters A, Vol. 385, 126958

  • Summary: Examines the influence of magnetic fields on the thermodynamic behavior of TMD-based quantum dots. Highlights changes in specific heat, entropy, and magnetization, which are key for quantum computing and thermoelectric devices.

6. Cumulative effects of fluctuations and magnetoelectric coupling in two-dimensional RMnO₃ (R = Tb, Lu and Y) multiferroics

  • Authors: G.E.T. Magne, R.M.K. Tsiaze, A.J. Fotué, N.M. Hounkonnou, L.C. Fai

  • Year: 2021

  • Citations: 10

  • Source: Physics Letters A, Vol. 400, 127305

  • Summary: Studies the interaction of critical fluctuations and magnetoelectric coupling in rare-earth manganite multiferroics. Offers theoretical support for the development of multifunctional spintronic devices.

7. Dynamics and decoherence of exciton polaron in monolayer transition metal dichalcogenides

  • Authors: C. Kenfack-Sadem, A.K. Teguimfouet, A. Kenfack-Jiotsa, R.M.K. Tsiaze

  • Year: 2021

  • Citations: 6

  • Source: Journal of Electronic Materials, Vol. 50 (5), 2911–2921

  • Summary: Investigates exciton-polaron behavior in 2D TMDs, especially focusing on quantum coherence loss and dynamical evolution. Provides insight into carrier dynamics relevant for optoelectronic device design.

8. Renormalized Gaussian approach to size effects and exchange interactions: Application to localized ferromagnets and amorphous magnets

  • Authors: R.M.K. Tsiaze, A.V. Wirngo, S.E.M. Tchouobiap, E. Baloïtcha, M.N. Hounkonnou

  • Year: 2018

  • Citations: 5

  • Source: Journal of Magnetism and Magnetic Materials, Vol. 465, 611–620

  • Summary: Applies Gaussian field methods to analyze magnetic size effects and exchange interactions, contributing to understanding localized and amorphous magnetic materials.

9. Effects of critical fluctuations and dimensionality on the jump in specific heat at the superconducting transition temperature: Application to YBa₂Cu₃O₇−δ, Bi₂Sr₂CaCu₂O₈, …

  • Authors: R.M. Keumo Tsiaze, A.V. Wirngo, S.E. Mkam Tchouobiap, A.J. Fotue, …

  • Year: 2016

  • Citations: 5

  • Source: Physical Review E, Vol. 93 (6), 062105

  • Summary: Explores how fluctuations and system dimensionality influence the heat capacity jump during superconducting transitions, offering insight into the thermodynamics of high-Tc materials.

10. Landau-Zener tunneling of qubit states and Aharonov-Bohm interferometry in double quantum wires

  • Authors: J.E. Danga, S.C. Kenfack, R.M.K. Tsiaze, L.C. Fai

  • Year: 2019

  • Citations: 4

  • Source: Physica E: Low-dimensional Systems and Nanostructures, Vol. 108, 123–134

  • Summary: Theoretically examines quantum state tunneling and interference phenomena in coupled quantum wires. Relevant for future quantum information transport systems.

11. Coherent nonlinear low-frequency Landau–Zener tunneling induced by magnetic control of a spin qubit in a quantum wire

  • Authors: S.E. Mkam Tchouobiap, J.E. Danga, R.M. Keumo Tsiaze, L.C. Fai

  • Year: 2018

  • Citations: 4

  • Source: International Journal of Quantum Information, Vol. 16 (06), 1850049

  • Summary: Studies the coherent control of qubit tunneling using low-frequency magnetic fields. Highlights prospects for non-destructive quantum gate operations.

12. Theoretical study of two biquadratically coupled order parameters: Application to two-dimensional multiferroics

  • Authors: G.E.T. Magne, R.M.K. Tsiaze, A.J. Fotué, L.C. Fai

  • Year: 2020

  • Citations: 2

  • Source: Journal of Magnetism and Magnetic Materials, Vol. 504, 166661

  • Summary: The paper develops a theoretical model for analyzing the coupling between electric and magnetic orders in 2D multiferroic materials. Crucial for the design of multifunctional materials in nanoelectronics.

📌 Conclusion

Dr. Keumo Tsiaze Roger Magloire is a well-rounded, visionary researcher and educator whose work transcends borders 🌍. With a strong educational base, active involvement in cutting-edge theoretical research, and an innate ability to communicate scientific ideas, he continues to make significant strides in physics. His current investigations into superconductivity, magnetism, and quantum systems reflect his deep curiosity and scientific rigor 🔍. Committed to both science and humanity, Dr. KEUMO balances his intellectual pursuits with a love for sports and social engagement ⚽. Fluent in multiple languages, skilled in computation, and grounded in pedagogy, he exemplifies the modern physicist-scholar. His journey is marked by innovation, adaptability, and impact—qualities that promise continued contributions to the global scientific community 🔬✨.

Pengxia Zhou | Physics | Best Researcher Award

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Prof. Dr. Pengxia Zhou | Physics | Best Researcher Award

Associate professor at Nantong University, China

Zhou Pengxia (Zhou Pengxia) 🎓, born on October 24, 1977 🎂, is a dedicated physicist and educator at the School of Physical Science and Technology, Nantong University 🇨🇳. With over two decades of experience, she has contributed significantly to condensed matter physics and multiferroic materials research ⚛️. She earned her Ph.D. from Nanjing University and conducted postdoctoral research at leading institutions in Singapore 🌏. As the principal investigator of an NSFC-funded project, she explores octahedral rotations in perovskite superlattices 🧪. Her work bridges teaching and innovation, advancing the frontiers of physics through both academia and international collaboration 🌟.

Professional Profile:

Orcid

🔹 Education and Experience 

📘 Education:

  • 🎓 1997–2001: Bachelor’s Degree in Physics – Yanbei Normal College

  • 📚 2001–2004: Master’s Degree in Condensed Matter Physics – Yangzhou University

  • 🧠 2011–2015: Doctor’s Degree in Physics – Nanjing University

🧑‍🏫 Professional Experience:

  • 🏫 2004–Present: Lecturer – Nantong University

  • 🌏 2017.10–2018.02: Visiting Scholar – Singapore University of Technology and Design

  • 🌐 2018.09–2019.08: Research Fellow – National University of Singapore

🔹 Professional Development 

Dr. Zhou Pengxia’s professional journey reflects her passion for physics and global academic growth 🌍📈. She has participated in international collaborations in Singapore, enriching her research and teaching perspectives 🇸🇬🔬. At Nantong University, she not only teaches but also mentors students in advanced materials science 🎓🧪. Her participation in cutting-edge research on perovskite superlattices and multiferroicity has positioned her as a recognized contributor in her field ⚛️. Through continual learning, overseas exchanges, and scientific leadership, Dr. Zhou remains committed to academic excellence and innovation in physical science education and research 📘🌟.

🔹 Research Focus 

Dr. Zhou Pengxia’s research is centered around condensed matter physics with a specific emphasis on multiferroic materials and perovskite superlattices 🧲⚡. She investigates how octahedral rotation affects multiferroicity, exploring mechanisms to enhance functional properties of complex oxides 🧪🧬. Her work contributes to the understanding and engineering of materials that exhibit both ferroelectric and magnetic properties – critical for next-generation electronic devices 💻🔋. With a focus on crystal structures and symmetry interactions, her research bridges fundamental science and potential applications in sensors, memory devices, and spintronics 🌐🔧. Zhou’s interdisciplinary approach adds great value to material innovation 🔍🧠.

🔹 Awards and Honors 

🏆 Awards & Honors:

  • 🌟 Principal Investigator – National Natural Science Foundation of China (2017–2019) for research on perovskite superlattices

  • 🎓 Invited Research Fellow – National University of Singapore (2018–2019)

  • 🌍 International Collaboration Grant – Singapore University of Technology and Design (2017–2018)

Publication Top Notes

1. Employing interpretable multi-output machine learning to predict stable perovskites in photovoltaics

Journal: Materials Today Communications, 2025
DOI: 10.1016/j.mtcomm.2025.112552
Summary:
This study leverages interpretable multi-output machine learning models to predict thermodynamically stable perovskite materials for photovoltaic applications. The key innovation lies in the simultaneous prediction of multiple material properties (e.g., stability, band gap, defect tolerance) using models that offer transparency into decision-making (e.g., SHAP values, decision trees). This work contributes to faster and explainable discovery of efficient perovskites for solar cell design.

2. A first-principles study on the multiferroicity of semi-modified X₂M (X = C, Si; M = F, Cl) monolayers

Journal: Physical Chemistry Chemical Physics, 2023
DOI: 10.1039/D2CP04575C
Summary:
This DFT-based study explores multiferroic behavior in 2D monolayers composed of X₂M (X = C, Si; M = F, Cl), highlighting their coexisting ferroelectric and magnetic properties. The findings suggest semi-modified 2D materials could serve as candidates for spintronic and memory devices, due to their tunable multiferroic characteristics.

3. Theoretical investigation of the magnetic and optical properties in a transition metal-doped GaTeCl monolayer

Journal: Physical Chemistry Chemical Physics, 2023
DOI: 10.1039/D3CP02313C
Summary:
This study investigates how doping GaTeCl monolayers with transition metals (e.g., Mn, Fe, Co) affects their magnetic and optical behavior. Using DFT, the authors show enhanced magneto-optical properties, suggesting that doped GaTeCl systems are promising for optoelectronic and spintronic devices.

4. Magnetism and hybrid improper ferroelectricity in LaMO₃/YMO₃ superlattices

Journal: Phys. Chem. Chem. Phys., 2019
Author: Pengxia Zhou
Summary:
This work presents a theoretical analysis of LaMO₃/YMO₃ (M, Y = transition metals) superlattices, showing hybrid improper ferroelectricity arising from coupling between octahedral tilting and rotations, along with magnetic ordering. The results support the design of multifunctional oxide heterostructures combining electric and magnetic orderings.

5. The excitonic photoluminescence mechanism and lasing action in band-gap-tunable CdS₁−ₓSeₓ nanostructures

Journal: Nanoscale, 2016
Author: Pengxia Zhou
Summary:
This paper discusses CdS₁−ₓSeₓ nanostructures with tunable band gaps. The team demonstrates strong excitonic photoluminescence and low-threshold lasing, linking optical properties to composition and quantum confinement. It provides a foundational understanding for nanoscale optoelectronic and laser devices.

6. Ferroelectricity driven magnetism at domain walls in LaAlO₃/PbTiO₃ superlattices

Journal: Scientific Reports, 2015
Author: Pengxia Zhou
Summary:
This study reveals that in LaAlO₃/PbTiO₃ superlattices, ferroelectric domain walls can induce localized magnetic moments due to lattice distortions and charge redistributions. This domain-wall magnetism introduces the potential for non-volatile magnetic memory controlled by ferroelectric domains.

Conclusion:

Dr. Zhou Pengxia is a suitable candidate for a Best Researcher Award, particularly in the fields of condensed matter physics and material science. Her leadership in nationally funded research, international collaboration experience, and long-standing academic service reflect a researcher committed to scientific advancement and knowledge dissemination. While her publication record and citation metrics were not provided, her PI role on an NSFC project suggests peer recognition and scholarly maturity.

Joshua Benjamin | Physics | Best Researcher Award

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Mr. Joshua Benjamin | Physics | Best Researcher Award

Lagos Nigeria at TYDACOMM Nigeria Limited, Nigeria

benjamin, joshua olamide is a dedicated scholar and researcher passionate about space physics, ionospheric studies, and space weather. He holds a first-class degree in pure and applied physics from Ladoke Akintola University of Technology and a distinction in space physics from the African University of Science and Technology. With experience in RF network planning and optimization, teaching, and research, he combines technical expertise with strong analytical skills. Proficient in MATLAB, Microsoft Office, and data analysis tools, he is committed to innovation, leadership, and academic excellence. His research contributes to understanding ionospheric models and their impact on space weather. 🚀📡

Professional Profile

Education & Experience 🎓💼

  • [2022] MSc in Space Physics (Distinction) – African University of Science and Technology 📡
  • [2019] B.Tech in Pure and Applied Physics (First Class) – Ladoke Akintola University of Technology 🔬
  • [2023 – Present] RF Network Planning & Field Test Engineer – TYDACOMM Nigeria Limited 📶
  • [2020 – 2021] NYSC Mathematics & Economics Teacher – Jofegal International School 📚
  • [2018] Internship at Perfect Seven Solar Company – Solar System Maintenance ☀️
  • [2011 – 2012] Mathematics Teacher – Fountain of Knowledge Group of School 📏

Professional Development 📖🔍

benjamin, joshua olamide has actively participated in multiple international colloquiums and workshops related to space science, GNSS, and ionospheric studies. He has certifications in health, safety, and environment (HSE Levels 1-3) and has completed training in soft skills, entrepreneurship, and critical thinking. His involvement in research and development, coupled with hands-on experience in field testing, data collection, and RF network optimization, showcases his versatility. Passionate about academic excellence, he regularly engages in professional training, leadership roles, and mentorship programs to enhance his expertise in space physics and its applications. 🌍🛰️

Research Focus 🔬🌌

benjamin, joshua olamide specializes in ionospheric physics, space weather, and solar-terrestrial interactions. His research explores the global climatological performance of ionospheric models using Swarm satellite electron density measurements, evaluating their accuracy and implications for GNSS and communication systems. He has worked on latitudinal electron density profiles, comparing SWARM measurements with IRI models, and studying biophysics applications. His goal is to improve predictive models for space weather impacts on Earth, ensuring the safety and reliability of communication and navigation technologies. His research contributes to scientific advancements in space physics and atmospheric studies. 🌞🌍📡

Awards & Honors 🏆🎖️

  • [2022] Best Graduating Student – Institute of Space Science and Engineering 🏅
  • [2022] Best Graduating Student – Department of Space Physics 🏆
  • [2019] Akinrogun Trust Fund Award 💰
  • [2019] Best WAEC Result – New Era High School 🏅
  • [2007] One of the Best Junior WAEC Results – Greater Tomorrow College 🎓

Publication Top Notes

  1. “Investigation of the global climatologic performance of ionospheric models utilizing in-situ Swarm satellite electron density measurements”
    This paper was published in Advances in Space Research, Volume 75, Issue 5, pages 4274-4290, in 2025. The authors are:

    • D. Okoh
    • C. Cesaroni
    • J.B. Habarulema
    • Y. Migoya-Orué
    • B. Nava
    • L. Spogli
    • B. Rabiu
    • J. Benjamin

    The study offers a comprehensive investigation into the climatologic performance of three ionospheric models when compared to in-situ measurements from Swarm satellites. The models evaluated are the International Reference Ionosphere (IRI), NeQuick, and a 3-dimensional electron density model based on artificial neural network training of COSMIC satellite radio occultation measurements (3D-NN). The findings indicate that while all three models provide fairly accurate representations of the Swarm measurements, the 3D-NN model consistently performed better across various conditions.

  2. “Global Comparison of Instantaneous Electron Density Latitudinal Profiles from SWARM Satellites and IRI Model”
    This paper was published in Advances in Space Research in 2025. The authors are:

    • J.O. Benjamin
    • D.I. Okoh
    • B.A. Rabiu

    This study focuses on comparing instantaneous electron density latitudinal profiles obtained from Swarm satellites with predictions from the IRI model. The comparison aims to assess the accuracy of the IRI model in representing real-time electron density variations observed by the Swarm mission.

For full access to these publications, you may consider visiting the publisher’s website or accessing them through academic databases such as IEEE Xplore or ScienceDirect. If you are affiliated with an academic institution, you might have institutional access to these resources.

Conclusion

Benjamin, joshua olamide stands out as a promising researcher in space physics, with notable contributions to ionospheric studies, climatology models, and research-driven technological applications. His exceptional academic achievements, research output, leadership roles, and technical expertise position him as a deserving candidate for the Best Researcher Award.

Bilal Ramzan | Physics | Best Researcher Award

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Dr. Bilal Ramzan | Physics and Astronomy | Best Researcher Award

Assistant Professor at University of Management and Technology Lahore Pakistan, Pakistan.

Dr. Bilal Ramzan is a distinguished astrophysicist and academic affiliated with the University of Agriculture, Faisalabad, Pakistan. As an HEC-approved Ph.D. supervisor, he has made significant contributions to the fields of astrophysics and space sciences. His research primarily focuses on cosmic rays, astrophysical plasma, and interstellar medium dynamics. With a strong academic background and extensive publication record, Dr. Ramzan has established himself as a leading researcher in his domain. He has collaborated with esteemed international scholars and presented his findings at global conferences. His work is widely cited, reflecting its impact on the scientific community. Dr. Ramzan is also deeply involved in mentoring young researchers, guiding them in theoretical and computational astrophysics. His dedication to advancing space sciences in Pakistan and beyond highlights his commitment to academic excellence and scientific discovery.

Professional Profile:

Education

Dr. Bilal Ramzan has a robust academic background, with a Ph.D. in Astronomy and Astrophysics from the Graduate Institute of Astronomy, National Central University, Taiwan, where he graduated in 2021 with a GPA of 3.4/4.0. He holds a Master’s degree in Physics from COMSATS Institute of Information and Technology, Lahore, Pakistan, completed in 2014, and a Bachelor’s degree in Physics from the same institution, obtained in 2011. Additionally, he pursued a Bachelor’s in Education from the University of Education, Lahore, in 2012. His early education includes pre-engineering studies at Nishtar College for Boys, Lahore, and matriculation from Nishtar School for Boys. His strong educational foundation in physics and astrophysics has equipped him with the necessary knowledge and skills to contribute significantly to space sciences and interstellar research.

Professional Experience

Dr. Bilal Ramzan is currently affiliated with the University of Agriculture, Faisalabad, Pakistan, where he serves as a researcher and academic mentor. His role as an HEC-approved Ph.D. supervisor enables him to guide doctoral candidates in cutting-edge astrophysical research. He has an extensive research background in cosmic-ray physics, astrophysical fluid dynamics, and magnetohydrodynamics. Dr. Ramzan has actively participated in numerous international conferences, presenting his findings on cosmic-ray-driven outflows and galactic evolution. His experience extends to collaborative projects with leading space research institutes, where he has contributed to numerical simulations and theoretical modeling of interstellar phenomena. His expertise is sought after for peer reviews, and he serves as a referee for reputed scientific journals in astrophysics. His professional career is marked by a commitment to scientific innovation, interdisciplinary collaboration, and academic leadership.

Research Interest

Dr. Bilal Ramzan’s research interests lie in the study of cosmic rays, astrophysical plasmas, interstellar medium dynamics, and space weather phenomena. He explores the impact of cosmic rays on galactic evolution, particularly in the formation of outflows and winds. His work delves into the behavior of astrophysical fluids under extreme conditions, utilizing magnetohydrodynamic (MHD) models to simulate cosmic-ray interactions. Dr. Ramzan is also interested in the applications of deep learning and quantum computing in astrophysics, focusing on algorithmic approaches to understanding space-time structures such as wormholes. His research integrates computational astrophysics with observational data, aiming to provide deeper insights into cosmic-ray propagation and the thermodynamic behavior of interstellar clouds. Through his studies, he seeks to unravel the fundamental mechanisms governing high-energy astrophysical processes.

Research Skills

Dr. Bilal Ramzan possesses advanced research skills in numerical simulations, theoretical modeling, and data analysis in astrophysics. His expertise in magnetohydrodynamics (MHD) allows him to develop computational models for cosmic-ray interactions and plasma dynamics. He is proficient in coding and utilizing high-performance computing techniques to simulate astrophysical environments. Dr. Ramzan is skilled in analyzing observational data from space telescopes and ground-based observatories, correlating theoretical models with real-world astronomical phenomena. His familiarity with deep learning and quantum algorithms enables him to explore innovative approaches in astrophysical research. He also has strong technical writing skills, with a track record of publishing in high-impact scientific journals. His ability to synthesize complex theoretical concepts into tangible research findings showcases his analytical acumen and scientific rigor.

Awards and Honors

Dr. Bilal Ramzan has received multiple recognitions for his contributions to astrophysical research. He has been invited to present his work at prestigious international conferences, including the COSPAR Scientific Assemblies and ASROC Meetings. His publications in renowned journals such as Astrophysical Journal, Astronomy & Astrophysics, and Scientific Reports reflect the high quality and impact of his research. His contributions to understanding cosmic-ray-driven outflows have been acknowledged by the scientific community, leading to collaborative opportunities with leading researchers. As an HEC-approved Ph.D. supervisor, he has also been recognized for his role in mentoring young scientists and advancing astrophysical research in Pakistan. His work continues to shape the field, earning him accolades for scientific excellence and academic leadership.

Publication Top Notes

  1. Galactic outflows in different geometries
    • Authors: Majeed, U., Ramzan, B.
    • Year: 2025
  2. A fluid approach to cosmic-ray modified shocks
    • Authors: Ramzan, B., Qazi, S.N.A., Salarzai, I., Rasheed, A., Jamil, M.
    • Year: 2024
    • Citations: 1
  3. The formation of invariant optical soliton structures…
    • Authors: Faridi, W.A., Iqbal, M., Ramzan, B., Akinyemi, L., Mostafa, A.M.
    • Year: 2024
    • Citations: 18
  4. Magnetoacoustics and magnetic quantization of Fermi states in relativistic plasmas
    • Authors: Iqbal, A., Rasheed, A., Fatima, A., Ramzan, B., Jamil, M.
    • Year: 2024
  5. Deep learning and quantum algorithms approach to investigating the feasibility of wormholes: A review
    • Authors: Rahmaniar, W., Ramzan, B., Ma’arif, A.
    • Year: 2024
    • Citations: 1
  6. Determination of the optical properties of tungsten trioxide thin film…
    • Authors: Adnan, M., Jamil, M.I., Ramzan, B., Ahmad, A., Ghani, M.U.
    • Year: 2024
  7. Propagation of dust lower hybrid wave in dusty magneto dense plasma…
    • Authors: Yaseen, A., Mir, Z., Ramzan, B.
    • Year: 2024
  8. Continuous solutions of cosmic-rays and waves in astrophysical environments
    • Authors: Irshad, K., Ramzan, B., Qazi, S.N.A., Rasheed, A., Jamil, M.
    • Year: 2023
    • Citations: 1
  9. Transonic plasma winds with cosmic-rays and waves
    • Authors: Ramzan, B., Mir, Z., Rasheed, A., Jamil, M.
    • Year: 2023
    • Citations: 2
  10. Kelvin-Helmholtz instability in magnetically quantized dense plasmas
  • Authors: Rasheed, A., Nazir, A., Fatima, A., Kiran, Z., Jamil, M.
  • Year: 2023

Conclusion

Dr. Bilal Ramzan’s remarkable contributions to astrophysics, his extensive publication record, and his commitment to academic mentorship make him a strong contender for the Best Researcher Award. His expertise in cosmic rays, space plasmas, and astrophysical fluid dynamics is evident in his high-impact research and international collaborations. His ability to integrate computational techniques with observational astrophysics highlights his innovative approach to scientific inquiry. While his achievements are significant, continued interdisciplinary collaborations and the pursuit of larger research grants could further enhance his influence in the field. Overall, Dr. Ramzan stands out as a leading researcher whose work is shaping the future of space science.

Uzma Tabassam | High Energy Physics | Best Researcher Award

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Dr. Uzma Tabassam | High Energy Physics | Best Researcher Award 

Dr. Uzma Tabassam, COMSATS University Islamabad, Islamabad Pakistan, Pakistan

Dr. Uzma Tabassam is a dedicated physicist specializing in experimental nuclear astrophysics and high-energy physics. With a Ph.D. from the University of Camerino, Italy, and extensive experience in particle detector technology, Dr. Tabassam is a leading figure in experimental nuclear research at COMSATS University Islamabad. She excels in particle detector fabrication, simulations, and spectroscopy, playing an active role in global physics collaborations like the ALICE experiment.

PROFILE

Google Scholar Profile

Educational Details

Dr. Tabassam completed her Ph.D. in Experimental Nuclear Astrophysics at the University of Camerino, Italy, from 2009 to 2012. She holds an MS in Physics with a specialization in Quantum Computation and Nano-science from COMSATS Institute of Information Technology, Islamabad, which she earned in 2008. Her foundational academic journey began with an MSc in Physics from Quaid-i-Azam University, Islamabad, from 2003 to 2006, followed by a BSc in Physics from Islamabad College for Girls, F-6/2, Pakistan, between 2001 and 2003.

Professional Experience

With a strong focus on experimental nuclear physics and high energy physics, Dr. Tabassam has been involved in various collaborative research projects, including the ALICE experiment at CERN. Her work entails using advanced simulation tools like GEANT4 and Monte Carlo event generators (HIJING2.0, PYTHIA8, UrQMD, EPOS-LHC, and more) for the analysis of particle interactions. She has extensive experience in detector construction, UHV fabrication, and operating sophisticated tools such as electron microscopes and spectroscopic detectors (NaI(Tl), HPGe, SSBD, BF3).

Research Interest

Experimental Nuclear Astrophysics

High-Energy Physics Phenomenology

Particle Detector Fabrication

GEANT4 Simulations

Particle Spectroscopy Her contributions to these fields help advance the understanding of particle interactions at the nuclear and astrophysical levels.

Skills and Competencies

Proficient in O2 software and AliRoot for ALICE experiment data analysis

Expertise in Monte Carlo event generators such as PYTHIA8, UrQMD, and EPOS

Advanced user of ROOT data analysis framework and GEANT4 simulations

C++ programming for simulation and analysis

Particle detector fabrication (UHV) and spectroscopy with detectors like NaI(Tl), HPGe, SSBD, and BF3

Experience with front-end electronics for alpha, beta, and gamma spectroscopy

Proficiency in Linux, Latex, Microsoft Word, and Origin for data analysis

Top Notable Publications

Enhanced production of multi-strange hadrons in high-multiplicity proton–proton collisions

Authors: J Adam, D Adamová, MM Aggarwal, G Aglieri Rinella, M Agnello, et al.

Journal: Nature Physics

Volume: 13 (6), Pages 535-539

Year: 2017

Citations: 1802

Anisotropic Flow of Charged Particles in Pb-Pb Collisions at

Authors: J Adam, D Adamová, MM Aggarwal, G Aglieri Rinella, M Agnello, et al.

Journal: Physical Review Letters

Volume: 116 (13), 132302

Year: 2016

Citations: 465

Production of charged pions, kaons, and (anti-)protons in Pb-Pb and inelastic collisions at TeV

Authors: S Acharya, D Adamová, SP Adhya, A Adler, J Adolfsson, MM Aggarwal, et al.

Journal: Physical Review C

Volume: 101 (4), 044907

Year: 2020

Citations: 450

Transverse momentum spectra and nuclear modification factors of charged particles in pp, p-Pb and Pb-Pb collisions at the LHC

Authors: S Acharya, FT Acosta, D Adamová, J Adolfsson, MM Aggarwal, et al.

Journal: Journal of High Energy Physics

Year: 2018 (11), Pages 1-33

Citations: 422

Measurement of D0, D+, D+ and Ds+ production in Pb-Pb collisions at TeV*

Authors: S Acharya, FT Acosta, D Adamová, J Adolfsson, MM Aggarwal, et al.

Journal: Journal of High Energy Physics

Year: 2018 (10), Pages 1-35

Citations: 421

Differential studies of inclusive J/ψ and ψ(2S) production at forward rapidity in Pb-Pb collisions at TeV

Authors: J Adam, D Adamová, MM Aggarwal, G Aglieri Rinella, M Agnello, et al.

Journal: Journal of High Energy Physics

Year: 2016 (5), Pages 1-49

Citations: 371

Multiplicity dependence of light-flavor hadron production in collisions at

Authors: S Acharya, FT Acosta, D Adamová, A Adler, J Adolfsson, MM Aggarwal, et al.

Journal: Physical Review C

Volume: 99 (2), 024906

Year: 2019

Citations: 335

Conclusion

Based on her academic credentials, significant research contributions, and extensive skillset, Dr. Uzma Tabassam is highly suitable for the Best Researcher Award. Her expertise in experimental high-energy physics and nuclear astrophysics, along with her involvement in global research collaborations, makes her a prime candidate to be recognized for her outstanding contributions to the scientific community.

 

 

Rachid Amrani | Physics | Best Researcher Award

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Dr. Rachid Amrani | Physics | Best Researcher Award

Dr. Rachid Amrani, University of Algiers, Algeria

Dr. Rachid Amrani is a faculty member at the University of Algiers, Algeria. He currently holds the position of Lecturer B, a role he has occupied since July 2023, after serving as Lecturer A from February 2018. Before that, he was an Assistant Professor at the University of Algiers from February 2017 to February 2018. Dr. Amrani has a strong research background, having worked as a Research Scientist at the Center of Development of Advanced Technologies (CDTA) in Algiers from March 2016 to January 2017. Earlier in his career, from 2011 to 2013, he served as a Research Assistant to Dr. Yvan Cuminal at the Institut D’électronique Du Sud (IES), CNRS, University of Montpellier, France. His academic and research experience spans various institutions, focusing on advanced technologies and electronics.

PROFILE

Scopus Profile

Educational Details

Dr. Rachid Amrani earned his Ph.D. from the University of Montpellier, France, in December 2013, with a thesis focused on the “Growth and Properties of Hydrogenated Silicon Thin Films Deposited Near the Nanocrystalline Amorphous Transition Region from Argon Diluted Silane Plasma.” This work reflects his deep expertise in the field of material sciences, particularly in the study of thin films. Prior to his doctoral studies, Dr. Amrani completed a Magister degree in Physics with a specialization in material sciences at Université d’Oran Es-Senia, Algeria, from 2001 to 2006. His Magister thesis explored the “Optical Properties of Nanocrystalline Silicon Films Prepared by RF Magnetron Sputtering.” His academic journey began at Université d’Oran Es-Senia, where he earned his undergraduate degree in Physics with a focus on Theoretical Physics between 1992 and 1997. Throughout his career, Dr. Amrani has demonstrated a strong foundation in both theoretical and applied physics, particularly in the study of nanomaterials and thin film technologies.

Research  Interest

Dr. Rachid Amrani’s research interests lie at the intersection of material sciences and nanotechnology, with a particular focus on the growth, deposition, and characterization of thin films. His expertise encompasses a range of advanced techniques, including Plasma Enhanced Chemical Vapor Deposition (PECVD), RF magnetron sputtering, and thermal evaporation. Dr. Amrani has extensive experience in cleanroom processes, such as UV lithography, chemical etching, and reactive ion etching, which are essential for fabricating precise nanostructures. His work in characterizing thin films involves sophisticated methods like ellipsometry, Raman scattering spectroscopy, and Atomic Force Microscopy (AFM), aiming to understand the optical and structural properties of nanocrystalline silicon films and other functional materials. Dr. Amrani’s contributions to the field are reflected in his numerous publications and presentations at international conferences, where he has shared his findings on nanomaterials for energy conversion, storage, and other cutting-edge applications in electronics and photonics.

Honours and Awards

The Journal of Non-Crystalline Solids (Elsevier) and the Journal of Nanotechnology (IOPscience) are both prestigious publications in their respective fields. The Journal of Non-Crystalline Solids focuses on the latest research in amorphous materials, including glasses, polymers, and composites, and is known for publishing cutting-edge studies that advance the understanding of non-crystalline structures. Meanwhile, the Journal of Nanotechnology provides a platform for the dissemination of research on nanoscience and nanotechnology, covering topics ranging from the synthesis and characterization of nanomaterials to their applications in various industries. These journals are widely recognized for their rigorous peer-review process and their role in promoting scientific advancements.

 

Top Notable Publications

Investigation of Structural Heterogeneities in Hydrogenated Nanocrystalline Silicon Thin Films from Argon-Diluted Silane Dusty Plasma PECVD

Authors: R. Amrani, F. Lekoui, F. Pichot, S. Oussalah, Y. Cuminal

Year: 2024

Journal: Vacuum

Volume: 229

Article ID: 113568

Citations: 0

Machine Learning-Based Method for Predicting C–V-T Characteristics and Electrical Parameters of GaAs/AlGaAs Multi-Quantum Wells Schottky Diodes

Authors: E. Garoudja, A. Baouta, A. Derbal, N. Sengouga, M. Henini

Year: 2024

Journal: Physica B: Condensed Matter

Volume: 685

Article ID: 415998

Citations: 0

Structural and Optical Properties of Highly Ag-Doped TiO2 Thin Films Prepared by Flash Thermal Evaporation

Authors: R. Amrani, F. Lekoui, E. Garoudja, S. Oussalah, S. Hassani

Year: 2024

Journal: Physica Scripta

Volume: 99(6)

Article ID: 065914

Citations: 0

Optical Parameters Extraction of Zinc Oxide Thin Films Doped with Manganese Using an Innovative Technique Based on the Dragonfly Algorithm and Their Correlation to the Structural Properties

Authors: K. Settara, F. Lekoui, H. Akkari, S. Oussalah, S. Hassani

Year: 2024

Journal: Journal of Ovonic Research

Volume: 20(3)

Pages: 365–380

Citations: 0

On the Substrate Heating Effects on Structural, Mechanical, and Linear/Non-Linear Optical Properties of Ag–Mn Co-Doped ZnO Thin Films

Authors: F. Lekoui, R. Amrani, S. Hassani, N. Hendaoui, S. Oussalah

Year: 2024

Journal: Optical Materials

Volume: 150

Article ID: 115151

Citations: 4

A B3LYP-D3 Computational Study of Electronic, Structural, and Torsional Dynamic Properties of Mono-Substituted Naphthalenes: The Effect of the Nature and Position of Substituent

Authors: A. Benalia, A. Boukaoud, R. Amrani, A. Krid

Year: 2024

Journal: Journal of Molecular Modeling

Volume: 30(3)

Article ID: 88

Citations: 2

Electrical Parameters Extraction of Diode Using Whale Optimization Algorithm

Authors: E. Garoudja, W. Filali, S. Oussalah, F. Lekoui, R. Amrani

Year: 2024

Conference: 2nd International Conference on Electrical Engineering and Automatic Control (ICEEAC 2024)

Citations: 0

Effect of Ti/TiN Thin Film Geometrical Design on the Response of RTDs

Authors: W. Filali, E. Garoudja, F. Lekoui, S. Oussalah, R. Amrani

Year: 2024

Conference: 2nd International Conference on Electrical Engineering and Automatic Control (ICEEAC 2024)

Citations: 0

Artificial Intelligence Approach to Analyze SIMS Profiles of 11B, 31P, and 75As in n- and p-type Silicon Substrates: Experimental Investigation

Authors: W. Filali, M. Boubaaya, E. Garoudja, S. Oussalah, N. Sengouga

Year: 2023

Journal: Zeitschrift für Naturforschung – Section A Journal of Physical Sciences

Volume: 78(12)

Pages: 1143–1151

Citations: 0

Elaboration and Characterization of Pure ZnO, Ag, and Ag-Fe

Thin Films: Effect of Ag and Ag-Fe Doping on ZnO Physical Properties

Authors: F. Lekoui, S. Hassani, E. Garoudja, O. Sifi, S. Oussalah

Year: 2023

Journal: Revista Mexicana de Fisica

Volume: 69(5)

Article ID: 051005

Citations: 3