Pedram Ayyobi | Finite Element | Best Researcher Award Posted on 04/10/202404/10/2024 by ScienceFather Pedram Ayyobi | Finite Element | Best Researcher Award Mr. Pedram Ayyobi, University of coimbra , Portugal. Dr. Pedram Ayyobi is a skilled civil engineer specializing in Earthquake Engineering with a Master’s degree from Amirkabir University of Technology (2014). Currently pursuing a Ph.D. at the University of Coimbra, he focuses on building performance, structural engineering, and seismic strengthening. With expertise in finite element simulations and material behavior, Pedram contributes to advancements in civil infrastructure through cutting-edge research. His work spans multiple fields, including vibroelasticity, heat transfer, and passive structural control. Pedram has authored several journal and conference papers, making significant strides in civil engineering and materials science. Publication profile Orcid Education & Experience: Ph.D. (Ongoing) – Universidade de Coimbra (2023-Present) Research focus: Building performance (acoustics & thermal) Master’s in Earthquake Engineering – Amirkabir University of Technology (2014) Thesis: “Evaluation of TMD systems in steel structures including soil-structure interaction” Bachelor’s in Civil Engineering – University of Guilan (2011) Researcher – Universidade do Minho (2021-2023) Projects: Structural reinforcement and strengthening using CFRP laminates Suitability for Best Researcher Award Pedram Ayyobi is an outstanding candidate for the Best Researcher Award, demonstrating exceptional dedication and contributions to the field of Civil Engineering, particularly in Earthquake Engineering. Currently conducting research at the University of Coimbra, Pedram combines his academic excellence with practical applications to advance the understanding of building performance, specifically in acoustics and thermal efficiency. His qualifications are rooted in a Master’s degree from Amirkabir University of Technology, where his thesis on Tuned Mass Damper (TMD) systems significantly contributed to understanding seismic responses in steel structures. Professional Development () Pedram Ayyobi has continuously expanded his expertise in the field of civil engineering through active research and practical applications. His experience includes working on advanced structural performance solutions, seismic vulnerability, and vibroelasticity. Pedram leverages finite element simulation and practical knowledge of construction materials to address challenges in passive structural control and soil-structure interaction. His involvement in various research fellowships, including those at Universidade de Coimbra and Minho, has strengthened his ability to innovate in the areas of structural engineering and building performance. With multiple publications and project contributions, Pedram is a forward-thinking researcher in the civil engineering community. Research Focus Pedram Ayyobi’s research primarily revolves around the performance of civil structures, focusing on seismic strengthening, passive structural control, and soil-structure interaction. His expertise in finite element simulation allows him to assess the behavior of various construction materials under stress, particularly in relation to viber elasticity and heat transfer. Pedram is passionate about improving building performance, including acoustics and thermal regulation. His work with carbon fiber reinforced polymer (CFRP) laminates further contributes to the development of advanced reinforcement techniques for structures. This research directly impacts the sustainability and resilience of civil engineering projects. Awards and Honors () Full Master’s Degree Grant – Amirkabir University of Technology (2012) Partial Bachelor’s Degree Grant – University of Guilan (2007) Publication Top Notes “Numerical Assessment of the Effect of CFRP Anchorages on the Flexural and Shear Strengthening Performance of RC Beams” (2024) [Cited by: 0] “Modelling the behavior of RC beams simultaneously strengthened for flexural and shear with CFRP systems” (2023) [Cited by: 0] “Parametric and numerical Finite Element simulation of wind turbine blades subjected to thermal residual stresses” (2023) [Cited by: 0] “Bond behaviour of a stick shape CFRP reinforcement applied according to the NSM-ETS strengthening techniques” (2023) [Cited by: 0] “Effects of nonlinear soil–structure interaction on the seismic response of structure-TMD systems subjected to near-field earthquakes” (2017) [Cited by: 20] “Genetic algorithm design of a soil–structure–damper system” (2015) [Cited by: 15] “Performance of steel structures with tuned mass dampers, including soil structure interaction” (2015) [Cited by: 0] Conclusion Pedram Ayyobi’s robust academic background, innovative research contributions, and active engagement in high-impact projects position him as an exemplary candidate for the Best Researcher Award. His ongoing work at the University of Coimbra exemplifies his commitment to enhancing building performance and structural safety in the face of seismic challenges. Pedram’s ability to integrate theory with practical applications, coupled with his collaborative spirit, not only enriches the academic community but also holds significant promise for advancing the field of civil engineering. His dedication and results-driven approach are key factors that make him an outstanding choice for this prestigious recognition.
Guillermo Riveros | computational | Best Researcher Award Posted on 09/07/202409/07/2024 by ScienceFather Guillermo Riveros | computational | Best Researcher Award Dr. Guillermo A. Riveros, U.S. Army Engineer Research and Development Center, United States. Dr. Guillermo A. Riveros is a Research Civil Engineer at the U.S. Army Engineer Research and Development Center (ERDC) in Vicksburg, United States. Since 1992, he has been a subject matter expert in areas such as Water Resources Infrastructure, Fatigue and Fracture Mechanics, Computational Fluid and Solid Mechanics, Structural Assessment of Aging Infrastructure, Bio-inspired Material Engineering, and Large Scale Additive Manufacturing. His innovative research has led to significant advancements in both civil and military engineering fields. Publication Profile Scopus Education and Experience Dr. Riveros received his BS and MS in Civil Engineering from the University of Puerto Rico at Mayagüez. He also earned an MS in Engineering Mechanics from Mississippi State University and a Ph.D. in Civil Engineering from the University of Missouri-Columbia. He has been with the ERDC since 1992, where he has significantly contributed to advancements in engineering computational modeling and analysis. Professional Development Throughout his career, Dr. Riveros has focused on developing innovative methods for fatigue and corrosion repairs using fiber-reinforced polymers, assessing military infrastructure, and exploring bio-inspired materials like Paddlefish. His work combines field measurements with sophisticated 3D finite element analysis to improve the longevity and efficiency of critical structures. Research Focus Dr. Riveros’s research includes cutting-edge areas such as computational and experimental mechanics of tainter gates and miter gates, fatigue and fracture mechanics, and bio-inspired material engineering. He aims to keep pace with rapid scientific and technological developments, producing tools and models that advance civil, military, and environmental research. Publications Deep Learning-Based Super Resolution Applied to Finite Element Analysis of Fused Deposition Modeling 3D Printing, 2024. Prediction of air filtration efficiency and airflow resistance of air filter media using convolutional neural networks and synthetic data derived from simulated media, 2023. Multi-axial fatigue behavior of high-strength structural bolts, 2023. Stabilized Electrospun Polyacrylonitrile Fibers for Advancements in Clean Air Technology, 2023. Alternative High-Performance Fibers for Nonwoven HEPA Filter Media, 2023. Modeling uniform random distributions of nonwoven fibers for computational analysis of composite materials, 2022. Basalt Fibers for Underwater Fatigue Repair of Steel Panels, 2022. The effects of deteriorated boundary conditions on horizontally framed miter gates, 2022. Digital twin geometry for fibrous air filtration media, 2021. Fiber selection for reinforced additive manufacturing, 2021.