Prof. Mohamed Ali | Fracture and Damage Mechanics | Editorial Board Member
Professor of Engineering Mathematics at Benha Faculty of Engineering | Benha University | Egypt.
Prof. Mohamed Ali is an Assistant Professor of Basic Science at Benha Faculty of Engineering, Benha University, specializing in advanced mathematical modeling, fractional calculus, nonlinear differential systems, numerical simulation, and analytical techniques applied to engineering and physical sciences. His academic journey includes a Bachelor’s degree in Electrical Power Engineering, followed by a Master’s and PhD in Engineering Mathematics and Physics focused on numerical solutions for differential and integral equations using innovative basis functions and comparative analyses of modern series solution frameworks. He has established a strong research presence in fractional ODEs and PDEs, fractional fluid flow problems, mixed convection, porous media flow, heat and mass transport, soliton theory, nanofluid and hybrid nanofluid dynamics, bio-convection, ordinary and partial differential systems, and advanced analytical and numerical methods. His professional expertise extends to computational software such as Mathematica, Maple, MATLAB, and scientific programming environments. Dr. Mohamed Reda has taught a wide range of foundational and advanced courses including Calculus, Differential Equations, Numerical Methods, Linear Algebra, Probability and Statistics, Operation Research, Research Methodology, and Specialized Topics in Analysis and Differential Equations. He has supervised postgraduate theses, delivered invited seminars, chaired academic committees, contributed to major mathematical conferences, and served as a part-time scientific consultant for multiple universities. His publication record spans hybrid orthonormal Bernstein and block-pulse function wavelet schemes for multidimensional nonlinear problems, Darboux transformation solutions for dispersive equations, numerical methods for singular Volterra systems, Lie symmetry analyses of nonlinear physical models, neural network-based computational intelligence for complex dynamical systems, nanofluid heat transport analysis, stochastic approaches for epidemiological and biological models, spectral relaxation frameworks, and innovative machine learning-assisted solvers for high-order nonlinear differential equations. His contributions continue to advance mathematical physics, computational engineering, and intelligent numerical algorithms.
Featured Publications:
Exploration of stagnation-point flow of Reiner–Rivlin fluid originating from the stretched cylinder for the transmission of the energy and matter. (2025). Scientific Reports.
Investigating the wave profiles to the linear quadratic model in mathematical biology. (2025). Scientific Reports.
Retraction Note: Nature analysis of Cross fluid flow with inclined magnetic dipole (Microsystem Technologies, (2023), 29(5), 697–714). (2025). Microsystem Technologies.
Thermal and entropic behavior of hybrid nanofluids in unsteady squeezing flow through porous media under magnetic influence. (2025). Results in Engineering.
Swarm intelligent computing procedures to solve the novel precautionary measures in the nonlinear HIV system. (2025). Multimedia Tools and Applications.