Professor. Zakaria Belabed holds advanced degrees in engineering, specializing in materials science and construction technology. His educational background is rooted in rigorous academic training and research, equipping him with expertise in the mechanical simulation of composite materials and structures. This solid educational foundation underpins his impactful contributions to engineering research and his role as a doctoral supervisor at the University Center Salhi Ahmed of Naama.
Professional Experience:
Professor. Zakaria Belabed serves as a distinguished academic and doctoral supervisor at the University Center Salhi Ahmed of Naama. With extensive expertise in engineering materials science and construction technology, he has guided numerous research projects. His professional experience includes pioneering studies in the mechanical simulation of composite materials and structures, reflecting his commitment to advancing innovation in engineering and construction.
🌍Research Contributions:
Professor. Zakaria Belabed has made impactful contributions to engineering materials science, focusing on nanocomposite beams, carbon nanotube-reinforced composites, and functionally graded materials. With 19 publications, an H-index of 11, and 992 citations, his research advances finite element modeling and vibrational analyses, addressing complex structural challenges and significantly enhancing knowledge in construction technology and materials science.
Significance and Recognition
Professor. Zakaria Belabed’s research is instrumental in advancing structural engineering, particularly through his innovative finite element modeling techniques. His work on nanocomposites and functionally graded materials addresses complex engineering challenges, providing solutions for dynamic responses, stability, and vibrational behavior. His contributions are highly regarded in academic circles, reflecting his significant influence in engineering materials science and construction technology.
Conclusion:
Professor. Zakaria Belabed’s outstanding publication metrics, extensive research in advanced material technologies, and sustained academic influence position him as a deserving candidate for the Best Researcher Award. His work not only advances engineering science but also inspires future research in the field.
Publication Top Notes:
“An efficient and simple higher order shear and normal deformation theory for functionally graded material (FGM) plates”
📰 Citations: 656 | Year: 2014
“A new 3-unknown hyperbolic shear deformation theory for vibration of functionally graded sandwich plate”
📊 Citations: 147 | Year: 2018
“Formulation and evaluation a finite element model for free vibration and buckling behaviours of functionally graded porous (FGP) beams”
🛠️ Citations: 87 | Year: 2023
“On the elastic stability and free vibration responses of functionally graded porous beams resting on Winkler-Pasternak foundations via finite element computation”
📐 Citations: 57 | Year: 2024
“Accurate free and forced vibration behavior prediction of functionally graded sandwich beams with variable cross-section: A finite element assessment”
🔍 Citations: 37 | Year: 2024
“Assessment of new 2D and quasi-3D nonlocal theories for free vibration analysis of size-dependent functionally graded (FG) nanoplates”
🌌 Citations: 26 | Year: 2019
“Free vibration analysis of Bi-Directional Functionally Graded Beams using a simple and efficient finite element model”
📏 Citations: 21 | Year: 2024
“An efficient higher order shear deformation theory for free vibration analysis of functionally graded shells”
🛠️ Citations: 16 | Year: 2021
“Investigation of influence of homogenization models on stability and dynamic of FGM plates on elastic foundations”
🏗️ Citations: 12 | Year: 2018
“Effect of homogenization models on stress analysis of functionally graded plates”
⚙️ Citations: 12 | Year: 2018
“Assessment of New Quasi-3D Finite Element Model for Free Vibration and Stability Behaviors of Thick Functionally Graded Beams”
🎚️ Citations: 10 | Year: 2024
“Free vibration analysis of porous functionally graded plates using a novel Quasi-3D hyperbolic high order shear deformation theory”
🌍 Citations: 10 | Year: 2023
“A new shear deformation shell theory for free vibration analysis of FG sandwich shells”
🌀 Citations: 9 | Year: 2021
“Mechanical behavior analysis of FG-CNTRC porous beams resting on Winkler and Pasternak elastic foundations: a finite element approach”
🏗️ Citations: 8 | Year: 2024
“Buckling behavior of nonlinear FG-CNT reinforced nanocomposite beam reposed on Winkler/Pasternak foundation”
🔧 Citations: 5 | Year: 2024
“On the Thermomechanical Behavior of Laminated Composite Plates using different Micromechanical-based Models for Coefficients of Thermal Expansion (CTE)”
🌡️ Citations: 3 | Year: 2024
“Effect of porosities on mechanical behavior and structural integrity of porous functionally graded plates using a new Quasi-3D trigonometric high order shear deformation theory”
🔬 Citations: 3 | Year: 2024
“Free vibration analysis of porous FG nanoplates via a new nonlocal 2D trigonometric high-order shear deformation theory”
🌌 Citations: 2 | Year: 2023
“On the free vibration behavior of carbon nanotube reinforced nanocomposite shells: A novel integral higher order shear theory approach”
🧪 Citations: 2 | Year: 2023