Dr. Meharu Fentahun Endalew | Best Researcher Award

Published on by Physics and Quantum Physics

Dr. Meharu Fentahun Endalew | Best Researcher Award

Beijing Institute of Mathematical Sciences and Applications (BIMSA) | China

Mehari Fentahun Endalew is a researcher affiliated with Debre Tabor University, Ethiopia, and the Beijing Institute of Mathematical Sciences and Applications (BIMSA), with a verified institutional email at dtu.edu.et. His academic background and professional experience are centered on applied mathematics and mathematical modeling, with a strong emphasis on fluid mechanics. His research focuses on hydromagnetic (MHD) flows, Casson and second-grade fluids, nanofluids, porous media, heat and mass transfer, dual-phase-lag heat transfer models, fractional calculus, and convection phenomena. Endalew has authored 19 peer-reviewed documents that have received 237 citations across 149 citing documents, resulting in an h-index of 9. His scholarly output includes publications in journals such as Boundary Value Problems, Heat Transfer,Asian Research, Scientific Reports, International Journal of Fluid Mechanics Research, Journal of Applied and Computational Mechanics, Engineering Reports, Fractal and Fractional, and Partial Differential Equations in Applied Mathematics. His work demonstrates sustained contributions to analytical, numerical, and temporal analyses of complex transport phenomena, including melting heat transfer, radiative effects, magnetic field inclination, chemical reactions, and slip conditions in porous and microchannel flows. Through interdisciplinary mathematical modeling, he continues to advance the theoretical understanding of fluid flow and heat and mass transfer processes.

Citation Metrics (Scopus)

250
150
100
50
0

Citations
237

Documents
19

h-index
9

Citations

Documents

h-index


View Google Scholar Profile
 View Scopus Profile

Featured Publications

Prof. Mohamed Othman | Best Researcher Award

Published on by Physics and Quantum Physics

Prof. Mohamed Othman | Best Researcher Award

Faculty of Science, Zagazig University | Egypt

Prof. Mohamed I. A. Othman is a distinguished scholar in applied mathematics whose extensive contributions to thermoelasticity, magneto-thermoelasticity, micropolar and microstretch continua, thermo-viscoelasticity, and wave propagation have established him as a leading figure in continuum mechanics research. With a prolific publication record exceeding 300 documents, an impressive h-index of 45+, and more than 6,500 citations, his work has significantly advanced theoretical and computational models in generalized thermoelasticity, fiber-reinforced materials, and multi-field coupling phenomena involving thermal, magnetic, rotational, and diffusion effects. He has collaborated widely with international researchers and consistently published in top journals such as International Journal of Solids and Structures, Applied Mathematical Modelling, and Journal of Thermal Stresses. His academic background includes advanced studies in mathematics with specialization in continuum mechanics and thermoelastic theory, followed by decades of research and teaching experience at leading scientific institutions. His research interests span plane wave propagation, multi-phase-lag theories, Green–Naghdi thermoelasticity, porous media, magneto-thermoelastic interactions, anisotropic materials, and domain-of-influence theorems. Throughout his career, Prof. Othman has received numerous recognitions for research excellence and scientific impact. His work continues to influence modern theoretical modeling in solid mechanics, offering foundational insights for emerging engineering and applied physics applications.

Profile : Google Scholar

Featured Publications

Othman, M. I. A., & Song, Y. (2007). Reflection of plane waves from an elastic solid half-space under hydrostatic initial stress without energy dissipation. International Journal of Solids and Structures, 44(17), 5651–5664.

Othman, M. I. A., & Marin, M. (2017). Effect of thermal loading due to laser pulse on thermoelastic porous media under G-N theory. Results in Physics, 7, 3863–3872.

Othman, M. I. A. (2004). Effect of rotation on plane waves in generalized thermoelasticity with two relaxation times. International Journal of Solids and Structures, 41(11-12), 2939–2956.

Othman, M. I. A., Said, S. M., & Marin, M. (2019). A novel model of plane waves of two-temperature fiber-reinforced thermoelastic medium under gravity with three-phase-lag model. International Journal of Numerical Methods for Heat and Fluid Flow, 29(12), 4788–4806.

Othman, M. I. A., Fekry, M., & Marin, M. (2020). Plane waves in generalized magneto-thermo-viscoelastic medium with voids under initial stress and laser pulse heating. Structural Engineering and Mechanics, 73(6), 621–629.

Dr. Mubbashar Nazeer | Editorial Board Member

Published on by Physics and Quantum Physics

Dr. Mubbashar Nazeer | Editorial Board Member

Government College University Faisalabad | Pakistan

Dr. Mubbashar Nazeer is a prominent researcher in applied mathematics, specializing in fluid mechanics, bio-fluids, nanofluid dynamics, heat transfer, cavity flows, and finite element analysis. With an h-index of 23, over 90+ documents, and more than 1,800 citations, his research has made significant contributions to nonlinear rheology, multiphase flow modeling, magnetohydrodynamics, and thermal transport in complex fluids. His academic journey includes advanced training in applied mathematics and computational fluid dynamics, followed by extensive experience in numerical modeling, perturbation methods, and simulation-based analysis of non-Newtonian fluid flows. Dr. Nazeer’s research consistently addresses real-world engineering and physiological flow problems, emphasizing novel rheological models such as Eyring–Powell, Casson, Rabinowitsch, Ellis, Jeffrey, and Maxwell fluids. He has collaborated widely across international research groups and published influential work in high-impact journals such as International Communications in Heat and Mass Transfer, Case Studies in Thermal Engineering, Surfaces and Interfaces, and Numerical Methods for Partial Differential Equations. His contributions have earned recognition within the fluid mechanics community, including acknowledgments for outstanding research productivity and high-impact publications. Overall, Dr. Nazeer remains committed to advancing computational modeling and thermal–fluid sciences through innovative problem-solving and interdisciplinary collaboration.

Profile : Google Scholar

Featured Publications

Nayak, M. K., Shaw, S., Khan, M. I., Pandey, V. S., & Nazeer, M. (2020). Flow and thermal analysis on Darcy–Forchheimer flow of copper–water nanofluid due to a rotating disk: A static and dynamic approach. Journal of Materials Research and Technology, 9(4), 7387–7408.

Chu, Y. M., Nazeer, M., Khan, M. I., Hussain, F., Rafi, H., Qayyum, S., & Abdelmalek, Z. (2021). Combined impacts of heat source/sink, radiative heat flux, temperature-dependent thermal conductivity on forced convective Rabinowitsch fluid. International Communications in Heat and Mass Transfer, 120, 105011.

Nazeer, M., Khan, M. I., Rafiq, M. U., & Khan, N. B. (2020). Numerical and scale analysis of Eyring–Powell nanofluid towards a magnetized stretched Riga surface with entropy generation and internal resistance. International Communications in Heat and Mass Transfer, 119, 104968.

Nazir, M. W., Javed, T., Ali, N., & Nazeer, M. (2021). Effects of radiative heat flux and heat generation on magnetohydrodynamics natural convection flow of nanofluid inside a porous triangular cavity. Numerical Methods for Partial Differential Equations.

Dr. Zhisong Ou | Best Researcher Award

Published on by Physics and Quantum Physics

Dr. Zhisong Ou | Best Researcher Award

Institute of Rock and Soil Mechanics, Chinese Academy of Sciences | China

Dr. Zhisong Ou is an Assistant Researcher at the Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, specializing in environmental geotechnical mechanics, multiphase flow dynamics, and thermo-hydro-mechanical-chemical (THMC) coupling processes. He earned his Ph.D. in geotechnical engineering and has gained extensive experience in computational modeling and experimental studies of flow and transport in porous media. Dr. Ou has authored 24 peer-reviewed publications, received 521 citations, and holds an h-index of 13, reflecting his impactful research contributions. His work focuses on advancing high-fidelity reacting immersed boundary methods, unified fluid–solid dynamics theories, and efficient one-field multiscale multiphysics models that enhance the understanding of coupled processes in geotechnical and environmental systems. As project leader for the National Natural Science Foundation of China Youth Fund and the CAS Special Research Assistant Project, he has led innovative research on contaminated site remediation, waste treatment, and sustainable infrastructure solutions. In addition, he serves on the Young Editorial Board of ICEST, contributing to the dissemination of knowledge in his field. Dr. Ou’s combination of theoretical insights, advanced modeling approaches, and problem-oriented research positions him as a rising research leader with strong potential to drive breakthroughs in environmental geotechnics and sustainable engineering.

Profile : Scopus

Featured Publications

Ou, Z., et al. (2025). Modeling and simulation of steam-enhanced extraction: Parameter effect of injected steam–air mixture on NAPL remediation at contaminated sites. Journal of Hazardous Materials.

Ou, Z., et al. (2025). A monolithic fluid–structure interaction approach for multiscale flows with deformable porous media. Physics of Fluids.

Ou, Z., et al. (2024). High-fidelity reacting immersed boundary method for interface-scale resolving simulations in porous media. Journal of Computational Physics.

Ou, Z., et al. (2023). Thermo-hydro-mechanical-chemical coupling analysis for waste containment barriers. Computers and Geotechnics.

Ou, Z., et al. (2022). Multiscale modeling of heat and mass transport in variably saturated soils under thermal gradients. International Journal of Heat and Mass Transfer.