Elbaz Abouelmagd | Elasticity | Editorial Board Member

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Prof. Elbaz Abouelmagd | Elasticity | Editorial Board Member

Join the Editorial Board Member Committee at National Research Institute of Astronomy and Geophysics | Egypt

Prof. Elbaz Abouelmagd widely recognized in scientific literature as Elbaz I. Abouelmagd, is an Egyptian associate professor of applied mathematics specializing in celestial mechanics and space dynamics, serving at the National Research Institute of Astronomy and Geophysics in Cairo, where he leads the Stellar Astronomy Laboratory and contributes to the advancement of space science research through a distinguished academic path built upon a Bachelor’s degree in mathematics, a Master’s degree in applied mathematics focused on the stability of Lagrangian points in the restricted three-body problem, an Aerospace Diploma in astronomy, and a doctoral degree centered on semi-analytical solutions for perturbed N-body systems under mutual gravitational forces with numerical applications; he has authored a substantial body of publications indexed under multiple global scientific identifiers including Scopus, Web of Science, MR Author ID, SciProfiles, and ISNI, reflecting a prolific research record with dozens of peer-reviewed papers, a strong citation impact, and a consistently high H-index across major international databases; his contributions span analytical modeling, orbital stability, dynamical systems, perturbation theory, and space dynamics, complemented by extensive academic appointments such as assistant and associate professorships across institutions in Egypt, Saudi Arabia, and Libya, as well as leadership roles in scientific committees, curriculum development, academic quality assurance, and national and international advisory boards including the International Astronomical Union, COSPAR, the American Mathematical Society, and various national committees in astronomy, space sciences, remote sensing, and scientific ethics; he has been repeatedly honored by NRIAG for scientific excellence and productivity and has supervised and hosted international scholars, maintaining an active presence in global research networks while advancing the theoretical and applied understanding of celestial mechanics through high-impact scientific contributions, institutional service, and international collaboration.

Profile:  Scopus | Orcid

Featured Publications:

Kumar, M., Pal, A. K., Verma, R. K., Ershkov, S., & Abouelmagd, E. I. (2026). Ring body problem dynamics under the albedo effect. International Journal of Non Linear Mechanics.

Vincent, A. E., Afere, B. A. E., Abouelmagd, E. I., & Elnashar, G. A. (2025). Continuation fraction perturbation effect on out-of-plane equilibrium points. Ingenieur Archiv.

Ma, B., Abouelmagd, E. I., & Gao, F. (2025). Periodic solutions of photo-gravitational R4BP with variable mass and Stokes drag. Nonlinear Dynamics.

Chauhan, S., Kumar, D., Aggarwal, R., Abouelmagd, E. I., & Elnashar, G. A. (2025). Revealing the albedo’s impact on the dynamics of the perturbed restricted three-body problem. Communications in Nonlinear Science and Numerical Simulation.

Suraj, M. S., Abouelmagd, E. I., Bhushan, M., & Asique, M. C. (2025). Exploring the equilibrium dynamics of an infinitesimal body in the perturbed problem of five bodies. Chaos, Solitons & Fractals.

Qimin Liu | Elasticity | Editorial Board Member

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Assoc. Prof. Dr. Qimin Liu | Elasticity | Editorial Board Member

Associate Professor at Wuhan university of technology | China

Assoc. Prof. Dr. Qimin Liu is a leading researcher at the Wuhan University of Technology whose multidisciplinary expertise spans mechanics of materials, multiphysics modeling, and smart materials & structures, and his scientific journey is defined by innovative work such as Transformation of Hard Pollen into Soft Matter, which reflects his early commitment to exploring unconventional material behaviors, followed by impactful biomedical advances including pioneering mechanobiology-driven strategies exemplified by Mechano-Activated Cell Therapy for Accelerated Diabetic Wound Healing and Mechano-Responsive Hydrogel for Direct Stem Cell Manufacturing to Therapy, demonstrating his ability to bridge materials science with regenerative medicine. His engineering-focused contributions include major additive manufacturing insights through A Quasi-Exponential Distribution of Interfacial Voids and Its Effect on the Interlayer Strength of 3D Printed Concrete, as well as breakthroughs in smart sensing technologies highlighted in Flexible, Programmable Sensing System with Poly (AAm-HEMA-SA) for Human Motion Detection, showcasing a strong commitment to innovations in structural sensing. Liu has extensively advanced intelligent hydrogel systems through a suite of multiphysics-driven works such as Development of a Multiphysics Model to Characterize the Responsive Behavior of Magnetic-Sensitive Hydrogels with Finite Deformation, Optimization of Deformable Magnetic-Sensitive Hydrogel-Based Targeting System in Suspension Fluid for Site-Specific Drug Delivery, Multiphysics Modeling of Responsive Deformation of Dual Magnetic-pH-Sensitive Hydrogel, A Multiphysics Model of Magnetic Hydrogel Under a Moving Magnet for Targeted Drug Delivery, A Transient Simulation to Predict the Kinetic Behavior of Magnetic-Sensitive Hydrogel Responsive to Magnetic Stimulus, and Modeling of a Fast-Response Magnetic-Sensitive Hydrogel for Dynamic Control of Microfluidic Flow. His interests further expand into acoustics and metamaterials through works like A Review of Acoustic Luneburg Lens: Physics and Applications and Acoustic Beam Splitter Based on Acoustic Metamaterial Luneburg Lens, as well as geomechanics and infrastructure resilience through Dynamic Mechanical Response and Particle Breakage Characteristics of Calcareous Sand and energy systems via Concentrating Efficiency Loss of Heliostat with Multiple Sub-Mirrors Under Wind Loads. Complementing these areas, he has contributed to membrane science and microreactor engineering through Divalent Ion Partitioning Through Dense Ion Exchange Membranes and Reaction-Diffusion Model to Quantify and Visualize Mass Transfer and Deactivation Within Core-Shell Polymeric Microreactors, along with research on material hydration processes in Hydration Kinetics of Portland Cement Shifting from Silicate to Aluminate Dominance Based on Multi-Mineral Reactions and Interactions. Collectively, these works establish Qimin Liu as a highly versatile scientist whose portfolio seamlessly integrates smart materials, biomechanics, energy systems, and multiphysics design, positioning him as a significant contributor to next-generation materials innovation.

Profile:  Scopus | Orcid | Google Scholar

Featured Publications:

Fan, T. F., Park, S., Shi, Q., Zhang, X., Liu, Q., Song, Y., Chin, H., Ibrahim, M. S. B., … (2020). Transformation of hard pollen into soft matter. Nature Communications, 11(1), 1449.

Shou, Y., Le, Z., Cheng, H. S., Liu, Q., Ng, Y. Z., Becker, D. L., Li, X., Liu, L., Xue, C., … (2023). Mechano-activated cell therapy for accelerated diabetic wound healing. Advanced Materials, 35(47), 2304638.

He, L., Chen, B., Liu, Q., Chen, H., Li, H., Chow, W. T., Tang, J., Du, Z., Yang He, J. P. (2024). A quasi-exponential distribution of interfacial voids and its effect on the interlayer strength of 3D printed concrete. Additive Manufacturing, 58, Article 103XXX (use final article number if available).

Shou, Y., Liu, L., Liu, Q., Le, Z., Lee, K. L., Li, H., Li, X., Koh, D. Z., Wang, Y., Liu, T. M., … (2023). Mechano-responsive hydrogel for direct stem cell manufacturing to therapy. Bioactive Materials, 24, 387–400.

Liu, Q., Li, H., & Lam, K. Y. (2017). Development of a multiphysics model to characterize the responsive behavior of magnetic-sensitive hydrogels with finite deformation. The Journal of Physical Chemistry B, 121(22), 5633–5646.

Ali Ozturk | Elasticity | Best Researcher Award

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Prof. Dr. Ali Ozturk | Elasticity | Best Researcher Award

Engineering Faculty at Duzce University | Turkey

Professor. Dr. Ali Öztürk is a distinguished academic and researcher in the field of Electrical and Electronics Engineering, renowned for his pioneering work on power system stability, optimization, and renewable energy integration. As a faculty member at Düzce University’s Faculty of Engineering, he has made substantial contributions to both academia and applied research through his expertise in intelligent control systems, genetic and heuristic algorithms, and power system analysis. His academic background, rooted in Electrical and Electronics Engineering from Sakarya University and Yıldız University, has provided a strong foundation for his innovative work on topics such as voltage stability, harmonic effects in power systems, and optimization of FACTS device placement. Professor Öztürk has supervised numerous master’s and doctoral theses focusing on advanced energy technologies, including solar and wind power systems, frequency control in multi-area power systems, and data-driven approaches to energy forecasting using deep learning. His research has been widely recognized in national and international projects, encompassing areas like photovoltaic system design, hybrid energy solutions, and the application of artificial intelligence in smart grid management. In addition to his extensive publication record in peer-reviewed journals, he has held several key administrative and academic leadership roles, including serving as Department Chair and Institute Director at Düzce University. Professor Öztürk’s ongoing work continues to bridge theoretical modeling and practical innovation, advancing sustainable energy systems and intelligent electrical network design through a combination of analytical rigor and technological creativity.

Profile: Scopus | Orcid 

Featured Publications:

A Novel Puma Optimizer Based TID Controller for Load Frequency Control.

Effects of Wind Turbine Height Variation on Hybrid Power System Feasibility.

Quantum Genetic Algorithm for Dynamic Economic Dispatch of Active Distribution Network with Microgrid Including Renewable Energy Source.

(2024). A Novel Sea Horse Optimizer Based Load Frequency Controller for Two-Area Power System with PV and Thermal Units. International Journal of Robotics and Control Systems.

(2023). A novel honey badger algorithm based load frequency controller design of a two-area system with renewable energy sources. Energy Reports.

Ali Raza Ayub | Elasticity | Best Researcher Award

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Mr. Ali Raza Ayub | Elasticity | Best Researcher Award

Student at Beijing Institute of Technology| Pakistan

Ali Raza Ayub is a dedicated Pakistani researcher and academic affiliated with the Department of Chemistry, University of Agriculture Faisalabad, Pakistan, with an active association in the Computational and Physical Chemistry Laboratories of the Punjab Bio Energy Institute. His research expertise lies primarily in organic and computational chemistry, emphasizing density functional theory (DFT), nonlinear optical (NLO) materials, organic solar cell materials, nanocomposites, and drug delivery systems. He has made remarkable contributions to the theoretical modeling, synthesis, and characterization of advanced materials, focusing on improving photocatalytic activity, optical properties, and molecular interactions. His studies cover a broad range of scientific topics, including nanochemistry, material science, quantum mechanical simulations, molecular spectroscopy, and bioactive nanomaterials. Through his extensive research, he has co-authored numerous internationally recognized publications in reputed scientific journals, demonstrating significant expertise in synthesizing metal-doped nanostructures, analyzing catalytic efficiencies, and investigating the optoelectronic behavior of advanced hybrid compounds. His computational work delves deeply into understanding molecular reactivity, charge transfer mechanisms, electronic structure modification, and energy efficiency optimization for next-generation materials. Ali Raza Ayub’s research also explores drug–nanocarrier interactions through DFT-based insights, providing theoretical foundations for targeted drug delivery applications in biomedical chemistry. His proficiency extends to laboratory instrumentation and advanced modeling software, such as Gaussian, GaussView, ChemDraw, Origin, and Multiwfn, enabling both experimental and theoretical studies of complex molecular systems. Beyond his research achievements, he has participated in international symposia, workshops, and scientific exhibitions, showcasing his commitment to academic excellence and innovation. Known for his creativity, analytical thinking, and persistence, Ali Raza Ayub continues to contribute to the evolving landscape of modern chemistry, merging computational precision with experimental discovery to advance materials science and chemical research.

Profile: Scopus 

Featured Publications:

Author(s). (2025). An in-silico study of supramolecular interactions between 2,6-diisopropylphenyl derivatives of PDI and their GMP-doped composites to tune their optoelectronic response. Inorganic Chemistry Communications.

Author(s). (2025). Investigating the optoelectronic properties of Perylene Diimide-based organic molecules for high-efficiency organic solar cells. Computational and Theoretical Chemistry.

Author(s). (2025). Terpyridine–metal architectures (Zn, Cu, Fe) for energy storage: Electrochemical analysis and theoretical modeling. Journal of Electroanalytical Chemistry.

Author(s). (2025). Design of the opto-electronic characteristics of organo-solar cells using the small molecules based on Ullazine. Journal of Molecular Graphics and Modelling.

Author(s). (2025). Quantum simulation and experimental characterization of gold nanorods for DNA sensing applications. Chemical Engineering Science.

Author(s). (2025). Green synthesis of high surface area of reduced graphene oxide via Aloe vera extract: Characterization, DFT mechanistic insights, and enhanced Rhodamine B adsorption using Chitosan@EDTA@rGO composite.