Sophia Immanuel | Textile-Reinforced Concrete | FRP Product Development Excellence Award

Published on by Fiber-Reinforced Polymer

Mrs. Sophia Immanuel | Textile-Reinforced Concrete | FRP Product Development Excellence Award

Research Scholar| National Institute of Technology, Tiruchirappalli|India

Mrs. Sophia Immanuel is an enthusiastic and highly motivated researcher in Textile-Reinforced Concrete with strong expertise in structural engineering and sustainable construction materials. She holds a Bachelor of Engineering in Civil Engineering from 2011 to 2015, followed by a Master of Technology in Structural Engineering with excellent academic performance, and a Doctor of Philosophy focused on advanced composite materials from 2022 to 2025. Additionally, she pursued an MBA in Human Resource Management through correspondence between 2020 and 2022. Her research expertise covers Textile-Reinforced Concrete, fibre reinforced composites, impact dynamics, structural dynamics, and magnetorheological dampers for seismic-resistant structures. Sophia has significant experimental experience in tensile behaviour of TRC composites, coir fibre characterization, tensile testing of Textile-Reinforced Concrete, and has received training in Digital Image Correlation technology. Her professional journey includes roles as a Project Intern at Flinders University, Assistant Professor (Guest) at Dr. B. R. Ambedkar Institute of Technology where she also served as NBA Coordinator and Faculty Advisor, and Project Officer at IIT Madras in the BTCM division. She has taught key structural engineering subjects to undergraduate students and was recognized with the Best Faculty Award in 2018. Sophia has published impactful research articles in reputed international journals such as Elsevier and Springer, contributing to the advancement of innovative TRC systems and sustainable low-cost housing. Proficient in tools like MATLAB, ABAQUS, AutoCAD, and Python basics, she continues to build strong collaborations with leading researchers while upholding integrity, dedication, and a deep sense of responsibility in her scientific pursuits.

Featured Publications

Immanuel, S., & Baskar, K. (2025). Low-velocity impact induced damage and dynamic response of two-way textile reinforced concrete slabs. Structures, 80, 110164.

Immanuel, S., & Baskar, K. (2025). Investigating the effect of textile layers on the flexural response of textile reinforced concrete panels. Structures, 71, 1108112.

Immanuel, S., O., Aniket, Baskar, K., & Arun, M. (2023). A state-of-art review on the mechanical performance of basalt textile reinforced concrete (BTRC). The Journal of Mechanics of Materials and Structures, 18(4), 593–618.

Immanuel, S., & Baskar, K. (2023). A state-of-the-art review on sustainable low-cost housing and application of textile reinforced concrete. Innovative Infrastructure Solutions, 8(1), 1–16.

Immanuel, S., & Kaliyamoorthy, B. (2023). Comparative study on the flexural behavior of BTRC and CTRC panels. In Structural Engineering Convention (pp. 569–579). Springer Nature Singapore.

Cruze, D., Gladston, H., Immanuel, S., Loganathan, S., Dharmaraj, T., & Solomon, S. M. (2018). Experimental investigation on magnetorheological damper for RCC frames subjected to cyclic loading. Advances in Civil Engineering Materials, 7(3), 413–427.

Destayehu Durressa | Mechanical Design | Editorial Board Member

Published on by Fiber-Reinforced Polymer

Assist. Prof. Dr. Destayehu Durressa | Mechanical Design | Editorial Board Member

Assist. Prof. Dr. Destayehu Durressa | Bahir Dar Institute of Technology | Ethiopia

Assist. Prof. Dr. Destayehu Durressa is a dedicated researcher in mechanical and materials engineering, with a strong emphasis on structural damage assessment, composite material behavior, and mechanical system reliability. His work centers on understanding how defects, cracks, and impact-induced damage influence the performance and durability of engineering components, contributing to safer and more efficient industrial applications. His early research involved analyzing the effect of cracks on spur gears in heavy-duty automotive gearboxes, providing insight into failure mechanisms and performance degradation in mechanical power-transmission systems. Building on this foundation, he has advanced his investigations into composite materials, focusing particularly on the characterization and modeling of residual elastic properties in impact-damaged glass-fiber composites. His publication in Results in Engineering (2025) demonstrates his commitment to rigorous experimental evaluation and predictive modeling, offering valuable contributions to material performance assessment and structural integrity research. Dr. Durressa’s scholarly efforts reflect a broader motivation to develop engineering solutions that enhance safety and reliability across industries, addressing challenges related to mechanical fatigue, material degradation, and system longevity. His research approach integrates practical experimentation with analytical modeling, aiming to support the development of more resilient components for automotive, aerospace, and manufacturing applications. Through his ongoing work, he continues to contribute meaningful advancements to the understanding of damage mechanics and material behavior, helping shape future innovations in mechanical engineering and composite material technologies.

Profile: Scopus

Featured Publications

Durressa, D. (2025). Characterization and modeling of residual elastic properties of impact-damaged glass fiber composite. Results in Engineering.