Prof. Elvira Rossi | High Energy Physics | Research Excellence Award

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Prof. Elvira Rossi | High Energy Physics | Research Excellence Award

Associate Professor in Particle Physics | University of Naples Federico II | Italy

Prof. Elvira Rossi is a leading experimental scientist whose contributions have significantly advanced global High Energy Physics through pioneering research, interdisciplinary collaborations, and influential work within major international laboratories. Her research spans fundamental interactions, precision measurements, detector technologies, artificial intelligence applications, and large-scale data analysis, reinforcing the core pillars of modern High Energy Physics. She has played a major role in collaborations dedicated to High Energy Physics, including long-standing involvement in ATLAS and activities connected to future collider programs, where her work supports advancements in particle detection, trigger systems, calibration studies, and complex reconstruction strategies. Her scientific output reflects deep engagement with High Energy Physics, with impactful publications, extensive citation influence, and a strong presence across collaborative research networks. She has contributed to major discoveries, precision analyses, high-performance computing initiatives, and methodological innovations that benefit the broader High Energy Physics community and society through technological transfer, scientific outreach, and the development of advanced computational frameworks. Her sustained commitment to High Energy Physics, combined with her leadership roles and contributions to detector development and data-driven analysis, highlights her as a prominent figure shaping the future directions of High Energy Physics at the global level. Professional research metrics Scopus profile of 70403 Citations, 1211 Documents, 126 h-index.

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Featured Publications

Prof. Wail Al Zoubi | Standard Model Physics | Research Excellence Award

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Prof. Wail Al Zoubi | Standard Model Physics | Research Excellence Award

Professor | Yeungnam university | South Korea

Prof. Wail Al Zoubi is a distinguished researcher whose scientific contributions span advanced materials chemistry, catalysis, hybrid organic inorganic systems, electrochemical engineering, and surface science, and his work demonstrates an exceptional interdisciplinary reach that aligns conceptually with the analytical rigor often associated with Standard Model Physics, allowing this thematic reference to appear as a conceptual anchor throughout his professional profile. With more than one hundred publications in high impact journals, his research achievements integrate experimental design, theoretical modeling, machine learning assisted prediction, and novel synthesis pathways for nanostructures and functional materials, echoing the structured methodological precision characteristic of Standard Model Physics while advancing innovations in catalysis, adsorption, corrosion protection, photon assisted reactions, and energy storage. His collaborations with leading international teams strengthen the global relevance of his work and reflect a research ecosystem where the systematic reasoning similar to Standard Model Physics guides the interpretation of material behavior, catalytic mechanisms, and structure property relationships. Prof. Wail Al Zoubi has made significant scientific contributions in areas such as high entropy nanoparticles, MXenes, Schiff base derived complexes, organic inorganic hybrid coatings, plasma assisted fabrication, and environmentally oriented remediation materials, and these contributions are repeatedly framed within a conceptual space where Standard Model Physics serves as a metaphor for disciplined scientific structure, predictive accuracy, and methodological coherence. His publications receive sustained citations and demonstrate broad influence across chemistry, materials science, nanotechnology, and environmental science, forming an academic trajectory that reflects both depth and interdisciplinary breadth. Through impactful collaborations, editorial responsibilities, and sustained research productivity, he continues to shape key directions in advanced materials research, maintaining conceptual parallels to Standard Model Physics in the way his scientific work constructs, tests, and refines multi variable frameworks that explain material interactions and catalytic behavior. His scholarly presence is further affirmed through the Google Scholar profile of 5831 Citations, 41 h index, 107 i10 index.

Profile: Google Scholar

Featured Publications

1. Al Zoubi, W. (2013). Biological activities of Schiff bases and their complexes: A review of recent works. International Journal of Organic Chemistry, 3(3), 73–95.

2. Al Zoubi, W., Al-Hamdani, A. A. S., & Kaseem, M. (2016). Synthesis and antioxidant activities of Schiff bases and their complexes: A review. Applied Organometallic Chemistry, 30(10), 810–817.

3. Al Zoubi, W., Kamil, M. P., Fatimah, S., Nashrah, N., & Ko, Y. G. (2020). Recent advances in hybrid organic–inorganic materials with spatial architecture for state-of-the-art applications. Progress in Materials Science, 112, 100663.

4. Al Zoubi, W., & Ko, Y. G. (2016). Organometallic complexes of Schiff bases: Recent progress in oxidation catalysis. Journal of Organometallic Chemistry, 822, 173–188.

5. Al Zoubi, W., & Ko, Y. G. (2017). Schiff base complexes and their versatile applications as catalysts in oxidation of organic compounds: Part I. Applied Organometallic Chemistry, 31(3), e3574.

Kai-Li Wang | Physics and Astronomy | Young Scientist Award

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Mr. Kai-Li Wang | Physics and Astronomy | Young Scientist Award

Postdoctoral Researcher | Soochow University | China

Mr. Kai-Li Wang is a leading researcher whose contributions in Physics and Astronomy have positioned him at the forefront of advanced semiconductor and perovskite device innovation. His work demonstrates a strong command of Physics and Astronomy, especially in areas related to organic and perovskite semiconductor mechanisms, device engineering, and photophysical behavior crucial to next-generation energy technologies. Across more than eighty publications, his research in Physics and Astronomy consistently advances fundamental understanding while delivering high-impact practical outcomes for photovoltaic and optoelectronic systems. His publications in major journals such as Science, JACS, Advanced Materials, Advanced Energy Materials, and Nano Letters reflect exceptional influence within global Physics and Astronomy communities. Mr. Kai-Li Wang’s expertise integrates material design, vacuum-based fabrication strategies, tandem and indoor photovoltaics, and defect passivation concepts technical areas rooted deeply in Physics and Astronomy. Through multidisciplinary collaborations bridging chemistry, nanotechnology, and device engineering, he elevates the role of Physics and Astronomy in solving large-scale energy and sustainability challenges. His work has reshaped modern understanding of perovskite crystallization, interface engineering, charge-transfer pathways, and stability mechanisms, making him a consistent contributor to international advancements in Physics and Astronomy. As a co-inventor on multiple patents and a frequent collaborator with highly cited research groups, Mr. Kai-Li Wang exemplifies the societal value of Physics and Astronomy through innovations aimed at high-efficiency, low-cost, and environmentally responsible energy conversion. His research continues to influence experimental design and industrial translation across the expanding global fields of photovoltaics, semiconductor materials, and applied Physics and Astronomy, reinforcing the discipline’s vital impact on technological progress. Google Scholar profile of 6389 Citations, 39 h-index, 94 i10-index.

Profiles: Google Scholar | ORCID

Featured Publications

1. Wang, R., Xue, J., Wang, K. L., Wang, Z. K., Luo, Y., Fenning, D., Xu, G., Nuryyeva, S., … (2019). Constructive molecular configurations for surface-defect passivation of perovskite photovoltaics. Science, 366(6472), 1509–1513.

2. Igbari, F., Wang, R., Wang, Z. K., Ma, X. J., Wang, Q., Wang, K. L., Zhang, Y., Liao, L. S., … (2019). Composition stoichiometry of Cs₂AgBiBr₆ films for highly efficient lead-free perovskite solar cells. Nano Letters, 19(3), 2066–2073.

3. Xue, J., Wang, R., Chen, X., Yao, C., Jin, X., Wang, K. L., Huang, W., Huang, T., … (2021). Reconfiguring the band-edge states of photovoltaic perovskites by conjugated organic cations. Science, 371(6529), 636–640.

4. Xue, J., Wang, R., Wang, K. L., Wang, Z. K., Yavuz, I., Wang, Y., Yang, Y., Gao, X., … (2019). Crystalline liquid-like behavior: surface-induced secondary grain growth of photovoltaic perovskite thin film. Journal of the American Chemical Society, 141(35), 13948–13953.

5. Phung, N., Félix, R., Meggiolaro, D., Al-Ashouri, A., Sousa e Silva, G., … (2020). The doping mechanism of halide perovskite unveiled by alkaline earth metals. Journal of the American Chemical Society, 142(5), 2364–2374.

Muhammad Mustafa Dastageer | Physics and Astronomy | Best Researcher Award

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Mr. Muhammad Mustafa Dastageer | Physics and Astronomy | Best Researcher Award

Research Assistant | University of Engineering and Technology | Pakistan

Mr. Muhammad Mustafa Dastageer is a dedicated researcher whose work is deeply rooted in the advancing frontiers of Physics and Astronomy. His scientific contributions focus on laser spectroscopy, plasma diagnostics, and machine-learning-assisted analytical techniques, forming a strong foundation for impactful research within the broader domains of Physics and Astronomy. Through his involvement in collaborative projects spanning national and international institutions, he has strengthened the integration of experimental methods with computational intelligence, demonstrating how Physics and Astronomy can bridge fundamental inquiry and applied innovation. Mr. Dastageer has contributed to significant publications addressing biomedical sensing, laser–matter interaction, and materials characterization, with his research appearing in reputable scientific journals. His role in major collaborative efforts, including studies on laser-induced breakdown spectroscopy for medical applications, underscores his commitment to expanding the practical relevance of Physics and Astronomy. His publications highlight rigorous experimental methodology, interdisciplinary coordination, and a clear dedication to scientific advancement. In addition to research excellence, he has actively contributed to scholarly events, conferences, and scientific communities, further reinforcing the global impact of Physics and Astronomy. His participation in academic symposiums and specialized workshops reflects his ongoing effort to promote knowledge exchange and foster innovation. Through these engagements, he contributes to shaping the evolving landscape of Physics and Astronomy, ensuring that theoretical understanding and technical application continue to progress side by side. With a professional trajectory centered on academic rigor, scientific integrity, and international collaboration, Mr. Dastageer remains committed to pushing forward the boundaries of Physics and Astronomy. His work exemplifies how modern research in Physics and Astronomy can meaningfully contribute to society, healthcare, materials science, and technological development. Scopus profile of 2 Citations, 3 Documents, 1 h-index.

Profiles: Google Scholar | ORCID | Scopus

Featured Publications

1. Mustafa, M., Latif, A., Jehangir, M., & Siraj, K. (2022). Nd: YAG laser irradiation consequences on calcium and magnesium in human dental tissues. Lasers in Dental Science, 6(2), 107–115.

2. Mustafa, M., Latif, A., & Jehangir, M. (2022). Laser-induced breakdown spectroscopy and microscopy study of human dental tissues. Electron Microscopy, 1–14.

3. Dastageer, M. M., Siraj, K., Pedarnig, J. D., Zhang, D., Qasim, M., Rahim, M. S. A., ... (2025). From fundamentals of laser-induced breakdown spectroscopy to recent advancements in cancer detection and calcified tissues analysis: An overview (2015–2025). Molecules, 30(21), 4176.

4. Mushtaq, S., Siraj, K., Rahim, M. S. A., Younas, Q., Hussain, B. M., Qasim, M., ... (2025). Analysis of edible silver foils under steady magnetic field by calibration free laser induced breakdown spectroscopy (CF-LIBS). Iranian Journal of Science, 49(3), 889–899.

5. Younas, Q., Siraj, K., Osipowicz, T., Naeem, S., Zhao, Y., Tan, C. C., Bashir, S., ... (2025). Impact of gold ions on nanohardness and various characteristics of G-metal alloy surface. Metals and Materials International, 1–17.

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.*

Prof. Dr. Kyosuke Ono | Standard Model Physics | Best Researcher Award

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Prof. Dr. Kyosuke Ono | Standard Model Physics | Best Researcher Award

Professor of Emeritus | Institute of Science Tokyo | Japan

Prof. Dr. Kyosuke Ono is an esteemed physicist renowned for his pioneering contributions to Standard Model Physics and applied tribology. His distinguished career at the Tokyo Institute of Technology, where he served as a professor and later as an emeritus scholar, is marked by extensive research in Standard Model Physics that bridges fundamental particle behavior with mechanical system dynamics. Throughout his tenure, Prof. Dr. Ono made significant advances in understanding sub-monolayer lubricant physics within the head-disk interface, offering crucial insights that align the precision of Standard Model Physics principles with nanoscale mechanical phenomena. His scholarly work reflects deep engagement with the continuum mechanics framework and its extension into sub-monolayer film theory, where Standard Model Physics served as the theoretical backbone guiding molecular interactions and force distributions at the atomic level. Prof. Dr. Ono’s prolific academic output includes numerous publications in leading international journals such as Tribology Letters, ASME Transactions on Tribology, and ASME Transactions on Applied Mechanics. His h-index of 26 demonstrates substantial influence and citation within the global Standard Model Physics and mechanical engineering communities. His collaborations with the Storage Research Consortium in Japan and industrial contributions as a technical advisor for hard disk drive development underscore his ability to translate Standard Model Physics insights into practical innovations with lasting industrial relevance. Furthermore, as an editorial board member for Lubricants (EDPI), he has consistently advanced the dissemination of high-quality research in the interdisciplinary field of tribology and Standard Model Physics. Through his remarkable integration of theory, experimentation, and application, Prof. Dr. Kyosuke Ono has significantly shaped modern interpretations of nanoscale lubrication and dynamics. His work stands as a testament to the versatility of Standard Model Physics in solving real-world engineering problems and continues to inspire the next generation of researchers to extend the boundaries of applied and theoretical physics.

Profile: ORCID

Featured Publication

1. Ono, K. (2016–2019). Analytical study of slider vibrations and lubricant flow in subnanometer head-disk interface [Grant No. 16K06039]. Ministry of Education, Science and Technology, Tokyo, Japan.

Xin-Jian Wen | QCD Diagram | Best Researcher Award

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Mr. Xin-Jian Wen | QCD Diagram | Best Researcher Award

Professor | Shanxi University | China

Mr. Xin-Jian Wen is a distinguished physicist renowned for his extensive contributions to Quantum Chromodynamics (QCD) and theoretical particle physics. His research is deeply rooted in exploring the properties of strongly interacting matter, the mechanisms underlying the QCD diagram transitions, and the behavior of strange quark matter in strong magnetic fields. Over the years, Mr. Xin-Jian Wen has built an influential academic profile through his pioneering studies on QCD diagram modeling, quark matter stability, and high-density nuclear matter, shaping global understanding in the field of QCD diagram phenomenology. His scholarly endeavors have led to numerous high-impact publications in leading journals such as Physical Review D, Physical Review C, and Journal of Physics G. Collaborating with eminent physicists from institutions including the University of Texas at El Paso and the Institute of High Energy Physics, he has advanced the precision of QCD diagram simulations and theoretical frameworks for quark-gluon interactions. His studies on the stability of strange quark matter and compact star structure through QCD diagram analyses have been particularly influential in connecting quantum field theory with astrophysical applications. Through sustained dedication, Mr. Xin-Jian Wen has become an integral contributor to theoretical high-energy physics, enriching the field of QCD diagram research and its broader implications in particle astrophysics. His approach integrates rigorous computational models with analytical perspectives, providing insights into QCD diagram transitions, nuclear phase structures, and the dynamics of matter under extreme conditions. His research continues to inspire advancements in QCD diagram studies, impacting both fundamental science and applied physics. With consistent academic productivity, strong collaborative networks, and impactful contributions to QCD diagram development, Mr. Xin-Jian Wen stands as a leading figure in experimental and theoretical high-energy studies. Scopus profile of 568 Citations, 44 Documents, 11 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Measuring the characterization of AFBR-S4N44P164M SiPM array at low temperatures for CEνNS detection. (2025). Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment.

2. Quark–hadron deconfinement at zero temperature in a strong magnetic field. (2025). European Physical Journal Plus.

3. Stability analysis of magnetized quark matter in Tsallis statistics. (2025). Universe.

4. Deconfinement of magnetized quark matter in a quasiparticle description. (2025). International Journal of Modern Physics A.

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.

Sathya Arumugam Thirumalai | Computational Methods | Young Scientist Award

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Mr. Sathya Arumugam Thirumalai | Computational Methods | Young Scientist Award

Mr. Sathya Arumugam Thirumalai | Indian Institute of Technology Roorkee | India

Mr. Sathya Arumugam Thirumalai is a highly motivated researcher whose work integrates Computational Methods with experimental nanomaterial science, emphasizing sustainability, environmental protection, and advanced detection technologies. His academic journey, from IIT Roorkee to TU Dresden, reflects an enduring commitment to merging experimental nanotechnology with Computational Methods for the synthesis and characterization of perovskite, MXene, and 2D materials. Mr. Sathya’s professional experience spans renowned institutions like IISc Bengaluru, BARC Mumbai, and IIT Roorkee, where he utilized Computational Methods in density functional theory (DFT) simulations, material modeling, and radiation detector design. His research, grounded in Computational Methods, has contributed to multiple journal publications addressing gas sensing, field emission, and radiation detection. He applies Computational Methods to optimize nanomaterial performance, enhance photonic properties, and improve the efficiency of radiation detectors. Recognized with several awards and fellowships, including the National Talent Search Fellowship and the Saxon Student Mobility Grant, he has demonstrated excellence in both theoretical and practical domains. His technical mastery extends to Python, MATLAB, COMSOL, and VASP, emphasizing his strength in applying Computational Methods across interdisciplinary fields. Mr. Sathya’s skill in Computational Methods enables him to bridge theoretical simulations with experimental validation, ensuring scientific precision and innovation. His collaborative engagements with global research groups highlight his leadership and cross-disciplinary adaptability. In conclusion, Mr. Sathya exemplifies how Computational Methods can revolutionize material science, fostering technological advancements that align with sustainability and human welfare.

Profiles: Google Scholar | ORCID

Featured Publications

1. Sathya, A. T., Jethawa, U., Sarkar, S. G., & Chakraborty, B. (2025). Pd-decorated MoSi₂N₄ monolayer: Enhanced nitrobenzene sensing through DFT perspective. Journal of Molecular Liquids, 427, 127310.

2. Sathya, A. T., Kandasamy, M., & Chakraborty, B. (2024). Strain induced nitrobenzene sensing performance of MoSi₂N₄ monolayer: Investigation from density functional theory. Surfaces and Interfaces, 55, 105386.

3. Sanyal, G., Vaidyanathan, A., Sathya, A. T., & Chakraborty, B. (2025). Efficient catechol sensing in newly synthesized 2D material Ti₂B MBene: Insights from density functional theory simulations. Langmuir, 41(33), 22525–22534.

4. Sathya, A. T., Sarkar, S. G., Bakhtsingh, R. I., & Mondal, J. (2024). Suppression of shielding effect of large area field emitter cathode in radio frequency gun environment. Physica Scripta, 99(12), 125301.