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.

Harsha Sai | Concrete | Best Researcher Award

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Mr. Harsha Sai | Concrete | Best Researcher Award

Mr. Harsha Sai | KL University | India

Mr. Harsha Sai is a dedicated structural engineering researcher whose work reflects strong technical depth, practical relevance, and a clear focus on advancing sustainable and high-performance construction materials. His research contributions span hybrid fiber–reinforced concrete, fly ash–based material optimization, GFRP and steel reinforcement behavior, and structural performance enhancement in diverse conditions. He has authored multiple peer-reviewed publications addressing mechanical behavior, flexural performance, and material durability, including studies on M40 concrete incorporating hybrid fibers and fly ash, comparative flexural analysis of GFRP and steel rebars in modified concrete mixes, and performance assessments of building designs on complex terrains. His work demonstrates a commitment to improving structural reliability, sustainability, and cost-effective engineering solutions. Alongside his research, he has presented at conferences and actively engaged in professional development through advanced software certifications and workshops related to sustainable construction, corrosion-free infrastructure, and emerging technologies such as 3D-printed concrete. He is proficient in advanced structural design and analysis tools including AutoCAD, ETABS, REVIT, and STAAD.Pro, enabling seamless integration between analytical research and practical engineering application. His experience in design consultancy, secondary steel detailing, and infrastructure component development further strengthens his ability to translate research insights into real-world engineering solutions. Through consistent scholarly output, hands-on project involvement, and participation in industry knowledge-sharing platforms, he has demonstrated a strong commitment to contributing to modern structural engineering challenges. His profile reflects an evolving researcher with the capability to drive innovation, support sustainable development goals, and contribute meaningful advancements to the field of structural engineering.

Profile: Scopus | Google Scholar | ResearchGate

Featured Publications

Khan, A. R., Rajesh, B., Prakash, B. J. P., & Varma, V. H. S. C. H. S. (2019). Design of a gravity dam. IJRAR – International Journal of Research and Analytical Reviews, 6(1), 4.

Sai, V. H., Lingeshwaran, N., Pratheba, S., & L. B. V. (2025). Enhanced mechanical and flexural performance of M40 concrete with hybrid fibers and fly ash replacement. Procedia Structural Integrity, 70, 509–516.

Vudata Harsha Sai, P. J., Lingeshwaran, N., Prasanna, P. K., & George Fernandez Raj, A. (2025). Flexural behavior of GFRP rebars and steel rebars with polypropylene fibers and fly ash-based concrete. Research on Engineering Structures and Materials, 17.

Navaneeth, L. N. V. H. S., Sravani, C., Koteswara Rao, & Thiyagarajan. (2025). Optimizing building design on sloping terrain: A comparative analysis of G+10 storied pre-engineered buildings on 10-degree slope and flat ground. International Journal of Materials, Mechanics, Mechatronics and Engineering, 2025.

Alper Bideci | Cementitious Materials | Best Review Paper Award

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Prof. Dr. Alper Bideci | Cementitious Materials | Best Review Paper Award

Academician | Düzce University | Turkey

Prof. Dr. Alper Bideci is a distinguished researcher specializing in building materials, with a particular focus on concrete, cement, composite materials, and coated aggregates. His research has significantly advanced the understanding of sustainable construction materials, especially in the development and application of polymer-coated lightweight aggregates and concretes that enhance mechanical performance, durability, and environmental efficiency. Dr. Bideci’s investigations encompass experimental and analytical studies on waste materials, polymer modifications, and the use of alternative aggregates to promote eco-friendly construction practices. His published works in leading journals such as Construction and Building Materials and Composites Part B: Engineering explore critical topics including the effects of hemp fibers on mortar performance, the influence of polymer admixtures on high-strength concretes, and life cycle assessment analyses of composite façade panels. Through his studies, he provides valuable insights into the chemical, mechanical, and petrographic characteristics of traditional and modern building materials, contributing to the advancement of sustainable material science and heritage restoration techniques. His findings on polymer-coated pumice aggregates and the utilization of industrial and agricultural waste materials in concrete have provided innovative solutions for both modern construction and environmental conservation. By integrating experimental rigor with sustainability principles, Dr. Bideci’s work bridges the gap between performance optimization and ecological responsibility, positioning him as a leading figure in the global research community dedicated to green construction technologies and advanced building material innovations.

Profile:  Scopus  |  ORCID Google Scholar  |  ResearchGate

Featured Publications

Çomak, B., Bideci, A., & Bideci, Ö. S. (2018). Effects of hemp fibers on characteristics of cement-based mortar. Construction and Building Materials, 169, 794–799.

Doğan, M., & Bideci, A. (2016). Effect of Styrene Butadiene Copolymer (SBR) admixture on high-strength concrete. Construction and Building Materials, 112, 378–385.

Bideci, A., Öztürk, H., Salli Bideci, Ö., & Emiroğlu, M. (2017). Fracture energy and mechanical characteristics of self-compacting concretes including waste bladder tyre. Construction and Building Materials, 149, 669–678.

Yılmaz, E., Arslan, H., & Bideci, A. (2019). Environmental performance analysis of insulated composite facade panels using life cycle assessment (LCA). Construction and Building Materials, 202, 806–813.

Bideci, Ö. S., Bideci, A., Gültekin, A. H., Oymael, S., & Yildirim, H. (2014). Polymer coated pumice aggregates and their properties. Composites Part B: Engineering, 67, 239–243.