Sathya Arumugam Thirumalai | Computational Methods | Young Scientist Award

Published on 15/10/202515/10/2025 by Physicist Particle

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.

Prof. Viktor Mykhas’kiv | Computational Methods | Best Researcher Award

Published on 15/10/202515/10/2025 by Physicist Particle

Prof. Viktor Mykhas’kiv | Computational Methods | Best Researcher Award

Leading Scientific Researcher | Institute for Applied Problemss of Mechanics and Mathematics | Ukraine

Prof. Viktor Mykhas’kiv is a distinguished researcher at the Pidstryhach Institute for Applied Problems of Mechanics and Mathematics, National Academy of Sciences of Ukraine. His academic achievements include a Doctor of Science in Physics and Mathematics and a professorship in Mechanics of Deformable Solids. His extensive expertise in Computational Methods spans across Computational Mechanics, Materials Science, Structural Mechanics, and Multiscale Mathematical Modeling. Through his pioneering work, he has applied Computational Methods to study wave propagation, metamaterials, and nanomechanics, advancing knowledge in multiple scattering theory. His research leadership in international collaborations under INTAS, STCU, DAAD, DFG, and Fulbright programs highlights his ability to integrate Computational Methods within global scientific frameworks. As a team leader and project manager, he has promoted innovative Computational Methods in the investigation of elastic metamaterials and complex lattice structures. He has published widely, authoring over seventy-six Scopus-indexed papers, two books, and contributing to editorial boards of international journals like Mathematical Methods and Physicomechanical Fields. His commitment to excellence in Computational Methods is reflected in his role as a member of the European Structural Integrity Society. He has also served as a visiting researcher in the USA and Germany, applying Computational Methods to solve advanced mechanical and physical problems. His awards and honors recognize his groundbreaking use of Computational Methods in applied mechanics and theoretical modeling. With remarkable research skills and professional integrity, Prof. Viktor Mykhas’kiv continues to contribute significantly to global scientific progress. Scopus profile of 474 Citations, 76 Documents, 14 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Stankevych, V. Z., & Mykhas’kiv, V. V. (2023). Intensity of dynamic stresses of longitudinal shear in a periodically layered composite with penny-shaped cracks. Journal of Mathematical Sciences, 269(2), 268–280.

2. Mykhas’kiv, V. V., & Stasyuk, B. M. (2021). Effective elastic moduli of short-fiber composite with sliding contact conditions at interfaces. Mechanics of Composite Materials, 57(6), 845–854.

3. Mykhas’kiv, V., & Stankevych, V. (2019). Elastodynamic problem for a layered composite with penny-shaped crack under harmonic torsion. ZAMM – Zeitschrift für Angewandte Mathematik und Mechanik, 99(8), e201800193.

4. Mykhas’kiv, V. V., Zhbadynskyi, I. Y., & Zhang, C. (2019). On propagation of time-harmonic elastic waves through a double-periodic array of penny-shaped cracks. European Journal of Mechanics - A/Solids, 74, 68–77.

5. Zhbadynskyi, I. Y., & Mykhas’kiv, V. V. (2018). Acoustic filtering properties of 3D elastic metamaterials structured by crack-like inclusions. Proceedings of the International Seminar/Workshop on Direct and Inverse Problems of Electromagnetic and Acoustic Wave Theory (DIPED), 54–59.

Prof. Nikolai V. Gaponenko | Physics | Best Researcher Award

Published on 14/10/202514/10/2025 by Physicist Particle

Prof. Nikolai V. Gaponenko | Physics | Best Researcher Award

Professor | Belarusian State University of Informatics and Radioelectronics | Belarus

Prof. Nikolai V. Gaponenko, a distinguished figure in physics, serves as Head of the Laboratory of Nanophotonics at the Belarusian State University of Informatics and Radioelectronics, where his extensive contributions to solid-state physics and nanophotonics have gained international recognition. His education in physics laid a robust foundation for pioneering research in optically anisotropic materials and sol-gel synthesis within the physics of photonic band gap structures. Throughout his professional experience, Prof. Gaponenko has led numerous interdisciplinary physics collaborations with global institutes, advancing luminescence technologies and nanostructure fabrication. His physics research encompasses photonic crystals, perovskite nanocomposites, and upconversion luminescence phenomena, with over a hundred high-impact publications and patents that redefine the role of physics in material design. Honored with several research distinctions, he has strengthened Belarus’s scientific presence through innovative physics-based solutions for electronic and photonic applications. His exceptional physics skills include experimental synthesis, spectroscopic analysis, and photonic modeling that bridge theory and engineering in nanophotonics. As an educator and physicist, he integrates practical and theoretical physics with creativity and leadership, inspiring scientific excellence. Prof. Nikolai V. Gaponenko’s career embodies the transformative potential of physics in shaping sustainable technological progress through deep insight, research integrity, and global collaboration.

Profiles: Google Scholar | ORCID

Featured Publications

1. Bogomolov, V. N., Gaponenko, S. V., Germanenko, I. N., Kapitonov, A. M., et al. (1997). Photonic band gap phenomenon and optical properties of artificial opals. Physical Review E, 55(6), 7619.

2. Dorofeev, A. M., Gaponenko, N. V., Bondarenko, V. P., Bachilo, E. E., Kazuchits, N. M., et al. (1995). Erbium luminescence in porous silicon doped from spin‐on films. Journal of Applied Physics, 77(6), 2679–2683.

3. Gaponenko, N. V., Davidson, J. A., Hamilton, B., Skeldon, P., Thompson, G. E., et al. (2000). Strongly enhanced Tb luminescence from titania xerogel solids mesoscopically confined in porous anodic alumina. Applied Physics Letters, 76(8), 1006–1008.

4. Lutich, A. A., Gaponenko, S. V., Gaponenko, N. V., Molchan, I. S., Sokol, V. A., et al. (2004). Anisotropic light scattering in nanoporous materials: A photon density of states effect. Nano Letters, 4(9), 1755–1758.

5. Gaponenko, N. V. (2001). Sol–gel derived films in meso-porous matrices: porous silicon, anodic aluminum and artificial opals. Synthetic Metals, 124(1), 125–130.

Dr. Bahadir Kopcasiz | Computational Methods | Best Researcher Award

Published on 17/09/202517/09/2025 by Physicist Particle

Dr. Bahadir Kopcasiz | Computational Methods | Best Researcher Award

Assistant Professor | Istanbul Gelisim University | Turkey

Dr. Bahadir Kopcasiz is an accomplished academic whose expertise centers on Computational Methods, with strong emphasis on nonlinear partial differential equations, soliton theory, symbolic and semi-analytical analysis, and advanced mathematical modeling. He earned his Ph.D. in Mathematics from Bursa Uludag University, preceded by a Master’s in Mathematics from Yeditepe University and a Bachelor’s from Karadeniz Technical University, building a solid foundation for his contributions in Computational Methods. Currently serving as an Assistant Professor at Istanbul Gelisim University, he actively teaches courses such as Differential Equations, Statistics, Probability, and Numerical Analysis, integrating Computational Methods into both undergraduate and graduate programs. His research primarily focuses on soliton solutions in nonlinear Schrödinger-type systems, dynamical structures in quantum physics, and the development of innovative Computational Methods to study complex dynamical systems, with numerous publications in high-impact journals including Archives of Computational Methods in Engineering, Nonlinear Dynamics, and Symmetry. He has also presented extensively at international conferences, showcasing advancements in Computational Methods for applied physics and engineering. Among his recognitions, he received the Best Researcher Award at the International Research Awards on Composite Materials and academic incentive awards from Istanbul Gelisim University, which highlight his outstanding scholarly contributions in Computational Methods. His research skills are distinguished by mastery of symbolic computation, semi-analytical modeling, and integration of Computational Methods with machine learning for dynamic system optimization, as evidenced by his involvement in national projects. In conclusion, Dr. Bahadir Kopcasiz exemplifies excellence in academia through his dedication to advancing Computational Methods, innovative problem-solving, impactful publications, and mentorship, establishing himself as a valuable contributor to mathematics, physics, and engineering research. His Google Scholar citations 337, h-index 12, i10-index 14, showcasing measurable research impact.

Profiles: Google Scholar | ORCID

Featured Publications

1. Kopçasız, B., & Yaşar, E. (2022). The investigation of unique optical soliton solutions for dual-mode nonlinear Schrödinger’s equation with new mechanisms. Journal of Optics, 1–15.

2. Kopçasız, B., & Yaşar, E. (2022). Novel exact solutions and bifurcation analysis to dual-mode nonlinear Schrödinger equation. Journal of Ocean Engineering and Science.

3. Kopçasız, B., & Yaşar, E. (2024). Dual-mode nonlinear Schrödinger equation (DMNLSE): Lie group analysis, group invariant solutions, and conservation laws. International Journal of Modern Physics B, 38(02), 2450020.

4. Kopçasız, B. (2024). Qualitative analysis and optical soliton solutions galore: Scrutinizing the (2+1)-dimensional complex modified Korteweg–de Vries system. Nonlinear Dynamics, 112(23), 21321–21341.

5. Kopçasız, B., Seadawy, A. R., & Yaşar, E. (2022). Highly dispersive optical soliton molecules to dual-mode nonlinear Schrödinger wave equation in cubic law media. Optical and Quantum Electronics, 54(3), 194.

Prof. Heshmatollah Yavari | Quantum Science | Best Academic Researcher Award

Published on 21/08/202521/08/2025 by Physicist Particle

Prof. Heshmatollah Yavari | Quantum Science | Best Academic Researcher Award

Researcher at University of Isfahan, Iran

Prof. Heshmatollah Yavari has established himself as a leading figure in Quantum Science, contributing significantly to the understanding of superconductivity, superfluidity, and condensed matter systems. His work consistently integrates Quantum Science with theoretical models and practical applications. Prof. Yavari’s expertise in Quantum Science spans ultracold atomic gases, optical lattices, and neutron star physics, offering deep insights into strongly correlated systems. His pioneering role in Quantum Science research has positioned him among scholars who shape the evolution of modern physics. Prof. Yavari has consistently advanced Quantum Science through publications, collaborations, and innovative teaching. His vision within Quantum Science demonstrates a balance between theoretical foundations and cutting-edge applications, ensuring that Quantum Science remains central to future technological advances.

Professional Profile

ORCID Profile | Scopus Profile

Education

Prof. Heshmatollah Yavari pursued his academic path with a clear dedication to Quantum Science, beginning with foundational studies in physics and advancing into specialized training in theoretical physics. His academic journey reflects a continuous engagement with Quantum Science, from undergraduate exploration to doctoral research. Prof. Yavari’s academic contributions reveal a strong commitment to Quantum Science, particularly in understanding transport phenomena, superconductors, and superfluids. Through each stage of education, Quantum Science remained the guiding principle of his learning and research. Prof. Yavari developed deep theoretical knowledge of Quantum Science, complemented by practical research projects that reinforced his scholarly standing. This trajectory highlights how Quantum Science shaped his intellectual development and prepared him for a lifetime of contribution to global scientific discovery.

Experience

Prof. Heshmatollah Yavari’s professional career exemplifies dedication to Quantum Science, demonstrated through decades of teaching, mentoring, and research leadership. His role as professor of physics at the University of Isfahan highlights his continuous contribution to Quantum Science across multiple levels of academia. He has guided numerous students into advanced areas of Quantum Science, fostering innovation and critical thinking. His lectures on advanced quantum mechanics, statistical mechanics, and field theory exemplify the integration of Quantum Science with core theoretical frameworks. As a professional, Prof. Yavari actively collaborates with international scholars, expanding Quantum Science into interdisciplinary domains. His administrative roles and research coordination further underline his commitment to ensuring Quantum Science thrives as both a teaching discipline and a global research frontier.

Research Interest

Prof. Heshmatollah Yavari’s research interests are firmly grounded in Quantum Science, with a focus on superconductivity, Bose-Einstein condensation, ultracold atomic gases, and topological insulators. His scholarly work connects Quantum Science with the mysteries of neutron stars, strongly correlated systems, and Majorana fermions. Prof. Yavari consistently expands the boundaries of Quantum Science by developing theories and models that address both fundamental and applied physics. Quantum Science drives his investigations into spin transport, optical lattices, and nonlocal effects in superconductors. His work reveals how Quantum Science contributes to understanding universal phenomena, from nanoscale materials to astrophysical systems. By integrating theory with experimental possibilities, Prof. Yavari demonstrates the transformative potential of Quantum Science across diverse scientific landscapes, ensuring it remains vital to modern physics.

Award and Honor

Prof. Heshmatollah Yavari has received recognition for his excellence in Quantum Science, reflecting his significant academic and research achievements. Awards and honors granted to Prof. Yavari underscore his enduring contributions to Quantum Science and theoretical physics. His published works in leading journals highlight the respect he commands in the Quantum Science community. Each accolade represents acknowledgment of his outstanding role in shaping Quantum Science and inspiring future generations of researchers. Honors received are not only a personal achievement but also evidence of his commitment to advancing Quantum Science globally. Through academic excellence and influential publications, Prof. Yavari’s reputation continues to strengthen, ensuring his name remains synonymous with quality and leadership in the growing field of Quantum Science.

Research Skill

Prof. Heshmatollah Yavari demonstrates advanced research skills in Quantum Science, applying both theoretical and computational methods to complex problems in physics. His expertise includes modeling superconductivity, analyzing transport properties, and interpreting Quantum Science phenomena in condensed matter systems. Prof. Yavari has mastered Quantum Science techniques related to ultracold atoms, superfluids, and nanoscale structures. His ability to integrate Quantum Science with interdisciplinary domains makes his skillset unique and impactful. Collaborations with other experts further amplify his Quantum Science research capabilities. His analytical approaches, problem-solving methods, and innovative thinking establish him as a skilled leader in Quantum Science. These research skills ensure that Prof. Yavari continuously contributes new insights and strengthens the foundation of Quantum Science in both academic and applied contexts.

Publication Top Notes

Title: Purity of entangled photon pairs in a semiconductor–superconductor heterostructure in the presence of both Rashba and Dresselhaus SOCs
Authors: Zahra Saeedi; Heshmatollah Yavari
Journal: Materials Research Bulletin

Title: Effects of Rashba and Dresselhaus spin-orbit couplings on the critical temperature and paramagnetic limiting field of superconductors with broken inversion symmetry
Authors: H. Yavari; M. Tayebantayeba
Journal: Physica C: Superconductivity and its Applications

Title: Impurity and hybridization effects on the symmetry classification and magnetic response function of a two-band superconductor with interband pairing order
Authors: F Aghamohammadi Renani; H Yavari
Journal: Progress of Theoretical and Experimental Physics

Title: Three-body and Coulomb interactions in a quasi-two-dimensional dipolar Bose-condensed gas
Authors: Heshmatollah Yavari
Journal: Annals of Physics

Title: Effects of hybridization and spin–orbit coupling to induce odd-frequency pairing in two-band superconductors
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Shear viscosity in the strong interaction regime of a p-wave superfluid Fermi gas
Authors: Heshmatollah Yavari
Journal: Physics Letters A

Title: Anomalous viscosity of a chiral two-orbital superconductor in tight-binding model
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Progress in the development and construction of high temperature superconducting magnets
Authors: Heshmatollah Yavari
Journal: Superconductor Science and Technology

Title: On the Properties of Novel Superconductors
Authors: Heshmatollah Yavari
Journal: IntechOpen

Title: Effects of Thermally Induced Roton‐Like Excitation on the Superfluid Density of a Quasi‐2D Dipolar Bose Condensed Gas
Authors: Heshmatollah Yavari
Journal: Annalen der Physik

Title: Effect of long-range 1/r interaction on thermal and quantum depletion of a dipolar quasi-two-dimensional Bose gas
Authors: Heshmatollah Yavari
Journal: Low Temperature Physics

Title: Phase-dependent heat current of granular Josephson junction for different geometries
Authors: Heshmatollah Yavari
Journal: Physics Letters A

Title: Edge currents as a probe of the strongly spin-polarized topological noncentrosymmetric superconductors
Authors: Heshmatollah Yavari
Journal: Physical Review B

Title: Hall viscosity of a chiral two-orbital superconductor at finite temperatures
Authors: Heshmatollah Yavari
Journal: Physica C: Superconductivity and its Applications

Title: Temperature Dependence of the Thermal Conductivity of a Trapped Dipolar Bose-Condensed Gas
Authors: Heshmatollah Yavari
Journal: Brazilian Journal of Physics

Title: Low-Temperature Dependence of the Shear Viscosity in Superconductor S r 2 R u O 4
Authors: Heshmatollah Yavari
Journal: Journal of Superconductivity and Novel Magnetism

Title: Effect of nonlinearity, magnetic and nonmagnetic impurities, and spin-orbit scattering on the nonlocal microwave response of ad-wave superconductor
Authors: Heshmatollah Yavari
Journal: Low Temperature Physics

Title: Landau damping in a dipolar Bose–Fermi mixture in the Bose–Einstein condensation (BEC) limit
Authors: Heshmatollah Yavari
Journal: Chinese Physics B

Title: Depletion of the condensate in a dipolar Bose condensed gas in the presence of impurities
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Low temperatures shear viscosity of a two-component dipolar Fermi gas with unequal population
Authors: Heshmatollah Yavari
Journal: Annals of Physics

Conclusion

Prof. Heshmatollah Yavari’s career is a testament to the power of Quantum Science in shaping both knowledge and technology. His lifelong dedication to Quantum Science demonstrates how deep theoretical inquiry can lead to transformative discoveries. Prof. Yavari’s role as a professor, researcher, and author illustrates his enduring influence on Quantum Science. By nurturing students, publishing extensively, and advancing new ideas, he ensures that Quantum Science remains dynamic and progressive. His contributions prove that Quantum Science is not only central to academic inquiry but also critical for global innovation. In conclusion, Prof. Yavari embodies excellence in Quantum Science, representing a model scholar whose legacy will continue to inspire future advancements in the ever-expanding universe of Quantum Science.

Assist. Prof. Dr. Kifle Adula Duguma | Computational Methods | Best Researcher Award

Published on 13/08/202513/08/2025 by Physicist Particle

Assist. Prof. Dr. Kifle Adula Duguma | Computational Methods | Best Researcher Award

Assistant Professor at Addis Ababa Science and Technology University, Ethiopia

Assist. Prof. Dr. Kifle Adula Duguma is a distinguished academic in the field of Computational Methods, dedicated to advancing knowledge in computational fluid dynamics, applied mathematics, and numerical analysis. His work on Computational Methods spans theoretical research, practical applications, and interdisciplinary collaboration. In his professional journey, Dr. Duguma has integrated Computational Methods into both undergraduate and postgraduate education, guiding students in research and project work. His publications in high-impact journals consistently emphasize Computational Methods for solving complex fluid flow, heat transfer, and porous media problems. By applying Computational Methods to nanofluid dynamics, magnetohydrodynamics, and hybrid modeling, he has contributed valuable insights to modern engineering problems. His academic leadership also promotes Computational Methods as a cornerstone of innovative problem-solving.

Professional Profile

ORCID Profile | Google Scholar Profile

Education

Assist. Prof. Dr. Kifle Adula Duguma has built his academic foundation through extensive studies in mathematics, numerical analysis, and computational fluid dynamics, always centered on Computational Methods. From undergraduate studies in mathematics to advanced doctoral research, Computational Methods formed the core of his learning. His doctoral thesis applied Computational Methods to complex flow and heat transfer problems, integrating theory with simulation. During his master’s degree, he refined his expertise in Computational Methods for solving nonlinear partial differential equations. Each academic stage strengthened his ability to innovate with Computational Methods, whether in finite element approaches, finite difference applications, or numerical modeling techniques. His training consistently reflects a deep engagement with Computational Methods, preparing him for impactful contributions in teaching and research.

Experience

Assist. Prof. Dr. Kifle Adula Duguma has extensive professional experience applying Computational Methods in both teaching and research. As an assistant professor, he has taught courses in applied mathematics, computational fluid dynamics, and numerical analysis, always embedding Computational Methods in lectures, laboratories, and projects. His leadership roles, including heading the mathematics division, emphasized curriculum design with strong Computational Methods components. His research applies Computational Methods to nanofluid flows, magnetohydrodynamics, hybrid models, and porous media. He supervises student projects that rely on Computational Methods for simulation and optimization. Across his career, Dr. Duguma has demonstrated that Computational Methods are essential in solving complex engineering problems, from industrial applications to academic challenges, ensuring students and peers value Computational Methods in their work.

Research Interest

Assist. Prof. Dr. Kifle Adula Duguma’s research interests revolve around the innovative application of Computational Methods in science and engineering. His primary focus areas include computational fluid dynamics, nanofluids, magnetohydrodynamics, electrohydrodynamics, and thermal transport phenomena, all driven by Computational Methods. He explores new algorithms, optimization techniques, and simulation strategies using Computational Methods for real-world problems. His studies in non-Newtonian fluids and hybrid nanofluids apply Computational Methods to enhance prediction accuracy and performance modeling. By integrating Computational Methods into multidisciplinary research, he addresses challenges in heat and mass transfer, stability analysis, and porous media flows. The consistent thread in his scholarly work is the advancement of Computational Methods as powerful tools for solving emerging engineering and scientific challenges worldwide.

Award and Honor

Assist. Prof. Dr. Kifle Adula Duguma’s academic achievements are closely linked to his pioneering contributions in Computational Methods. His recognition comes from publishing high-impact research where Computational Methods solve advanced engineering problems. Awards and honors highlight his leadership in integrating Computational Methods into both research and teaching. Serving as a journal reviewer, he evaluates work that applies Computational Methods across various domains. His leadership positions and contributions to academic communities are built upon advancing Computational Methods knowledge. These honors reflect not only technical expertise but also his ability to inspire others to apply Computational Methods in innovative ways. By consistently promoting Computational Methods, Dr. Duguma has earned respect as a leading figure in computational science and engineering.

Research Skill

Assist. Prof. Dr. Kifle Adula Duguma’s research skills are deeply rooted in Computational Methods, making him proficient in multiple numerical and analytical approaches. He expertly applies Computational Methods such as finite difference, finite element, finite volume, and Runge-Kutta techniques to model complex systems. His use of Computational Methods extends to software like MATLAB, Mathematica, Maple, and Python for simulation and analysis. He excels in data interpretation, algorithm development, and scientific computation, all grounded in Computational Methods. His capacity to integrate Computational Methods into experimental validation and theoretical frameworks strengthens his research output. Whether in teaching, mentoring, or publication, his skill set ensures Computational Methods remain central to his work and to the advancement of modern engineering practices globally.

Publication Top Notes

Title: Stability analysis of dual solutions of convective flow of casson nanofluid past a shrinking/stretching slippery sheet with thermophoresis and brownian motion in porous media

Authors: KA Duguma, OD Makinde, LG Enyadene

Journal: Journal of Mathematics

Title: Dual Solutions and Stability Analysis of Cu-H2O-Casson Nanofluid Convection past a Heated Stretching/Shrinking Slippery Sheet in a Porous Medium

Authors: KA Duguma, OD Makinde, LG Enyadene

Journal: Computational and Mathematical Methods

Title: Stagnation Point Flow of CoFe2O4/TiO2-H2O-Casson Nanofluid past a Slippery Stretching/Shrinking Cylindrical Surface in a Darcy–Forchheimer Porous Medium

Authors: KA Duguma, OD Makinde, LG Enyadene

Journal: Journal of Engineering

Title: Effects of buoyancy on radiative MHD mixed convective flow of casson nanofluid across a preamble slippery sheet in Darcy–Forchheimer porous medium: Shrinking/stretching surface …

Authors: KA Duguma

Journal: Numerical Heat Transfer, Part B: Fundamentals

Title: Stability Analysis of Dual Solutions of Convective Flow of Casson Nanofluid past a Shrinking/Stretching Slippery Sheet with Thermophoresis and Brownian Motion …

Authors: KA Duguma, OD Makinde, LG Enyadene

Journal: Journal of Mathematics

Conclusion

In conclusion, Assist. Prof. Dr. Kifle Adula Duguma’s career reflects unwavering dedication to Computational Methods in education, research, and professional service. His expertise ensures Computational Methods are applied rigorously across scientific domains, from computational fluid dynamics to nanotechnology. Through teaching, supervision, and publication, he promotes the strategic use of Computational Methods to solve critical engineering problems. His leadership in academic and research settings consistently elevates the role of Computational Methods as indispensable tools in modern science. By advancing Computational Methods methodologies, fostering innovation, and inspiring students, he has established a legacy that underscores the transformative power of Computational Methods in solving global scientific and technological challenges.

Assist Prof Dr. Amirali Amirsoleimani | AI Hardware design | Best Scholar Award

Published on 09/08/202409/08/2024 by Physicist Particle

Assist Prof Dr. Amirali Amirsoleimani | AI Hardware design | Best Scholar Award

Assist Prof Dr. Amirali Amirsoleimani, York University, Canada

Dr. Amirali Amirsoleimani is an Assistant Professor at York University, Canada, with a strong background in Electrical and Computer Engineering. His research is dedicated to advancing AI and neuromorphic computing by integrating CMOS technology with emerging memory solutions and bio-inspired algorithms. He has received numerous accolades for his contributions, including the IEEE Larry K. Wilson Award and the Alumni Odyssey Award from the University of Windsor. Dr. Amirsoleimani’s work is focused on developing cutting-edge technologies for efficient, high-performance computing systems in smart environments.

PROFILE

Orcid

Education

Ph.D. in Electrical and Computer Engineering (Sep 2014 – Dec 2017)

University of Windsor, Windsor, ON, Canada

Dissertation: In-Memory Computing by Using Nano-ionic Memristive Devices

Advisor: Dr. Majid Ahmadi

External Examiner: Dr. Manoj Sachdev

M.Sc. in Electrical and Computer Engineering (Sep 2011 – Sep 2013)

Razi University, Kermanshah, Iran

Dissertation: Process Variation Analysis of CMOS and CMOS-Memristor Logic Gates

Advisor: Dr. Arash Ahmadi

B.Sc. in Electrical and Computer Engineering (Sep 2006 – Sep 2010)

Razi University, Kermanshah, Iran

Dissertation: Intelligent Digital Thermal Measurement with USB Data Transfer Protocol

Advisor: Dr. Reza Keyhani

Research Interest

Dr. Amirali Amirsoleimani’s research focuses on developing ultra-efficient artificial intelligence (AI) and neuromorphic computing solutions. His work involves the integration of CMOS circuits with emerging memory technologies such as RRAM and PCRAM, as well as bio-inspired spike-based computing algorithms. His goal is to design fully-integrated in-memory computing systems, employing a software-hardware co-design approach. Dr. Amirsoleimani leads an interdisciplinary team of experts to create innovative solutions at the device, circuit, and software levels, aimed at achieving low-power, high-performance AI for smart environments.

Professional Experience

Dr. Amirali Amirsoleimani is an Assistant Professor at York University, Canada. He has been recognized for his contributions to the field with the IEEE Larry K. Wilson Award in 2016, which is awarded to a single recipient annually in Canada. Dr. Amirsoleimani was also honored with a Best Poster Honorable Mention at the IEEE International Joint Conference on Neural Network in 2017. His involvement in IEEE has been notable, with various recognitions including Certificates of Recognition for his roles and contributions within the IEEE Windsor Section. Additionally, he received the Graduate Student Society (GSS) Scholarship in 2016, further highlighting his achievements in the academic and research communities.

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