Ed-Dariy Yasmina | Concrete | Research Excellence Award

Published on by Fiber-Reinforced Polymer

Assist. Prof. Dr. Ed-Dariy Yasmina | Concrete | Research Excellence Award

Assistant Professor | National School of Architecture | Morocco

Assist. Prof. Dr. Yasmina ED-DARIY is an accomplished researcher in civil and environmental engineering, with extensive expertise in structural analysis and design, construction materials, geotechnical studies, building acoustics, environmental impact assessments, thermal and energy efficiency, and the strengthening of reinforced concrete using fiber-based composites. Her research has focused on sustainable construction and innovative concrete reinforcement methods, particularly the use of natural fibers such as jute for enhancing the mechanical performance of concrete members. She has contributed significantly to the understanding of the effects of alkali treatments and curing conditions on jute fiber-reinforced concrete, as well as the behavior of concrete cylinders and square columns strengthened with jute fiber-reinforced polymer (JFRP) composites. Her publications in peer-reviewed journals and presentations at international conferences reflect her commitment to advancing knowledge in concrete strengthening techniques using both synthetic and natural composites. Beyond her technical research, Dr. ED-DARIY actively engages in community and professional initiatives, having founded the Cultural Club at Centre Ajial and the Civil Engineering Club at FST Tangier, and served as Secretary-General of the Astronomy Association of Tangier. She has also organized outreach programs and events for orphaned children, demonstrating a strong commitment to social responsibility and the promotion of science in society. Her work exemplifies excellence in research, technical innovation, and societal impact, making her a highly deserving candidate for recognition through prestigious awards in research and innovation.

Profile: Scopus  | Google Scholar | ResearchGate

Featured Publications

  • Ed-Dariy, Y., Lamdour, N., Cherradi, T., Rotaru, A., Barbuta, M., & Mihai, P. (2020). Effect of alkali treatment of jute fibers on the compressive strength of normal-strength concrete members strengthened with JFRP composites. 淡江理工學刊, 23(4), 677–685.

  • Ed-Dariy, Y., Lamdouar, N., Cherrad, T., Rotaru, A., Barbuta, M., & Mihai, P. (2021). The influence of the curing conditions on the behavior of jute fibers reinforced concrete cylinders. Periodica Polytechnica Civil Engineering, 65(4), 1162–1173.

  • Ed-Dariy, Y., Lamdour, N., Cherradi, T., Rotaru, A., Barbuta, M., Mihai, P., … (2020). The behavior of concrete cylinders confined by JFRP composites: Effect of KOH solution. In 5th World Congress on Civil, Structural, and Environmental Engineering.

  • Ed-Dariy, Y., Lamdouar, N., Cherradi, T., Rotaru, A., Barbuta, M., … (2020). Experimental investigation of the effects of NaOH and KOH solution on the behavior of concrete square columns reinforced by JFRP composites. In 5th World Congress on Civil, Structural, and Environmental Engineering.

  • Ed-Dariy, Y., El Bhiri, B., & Deifalla, A. (2025). A review of concrete strengthening methods using synthetic and natural composites. Engineering Proceedings, 112(1), 35.

Sun Jae Yoo | Civil Engineering | FRP Engineering Excellence Award

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Dr. Sun Jae Yoo | Civil Engineering | FRP Engineering Excellence Award

Researcher | University of Illinois at Urbana-Champaign | United States

Dr. Sun-Jae Yoo is a leading researcher in advanced FRP engineering, with a strong focus on the structural performance, bond behavior, and durability of CFRP bars used in concrete systems under normal and extreme conditions. His work significantly advances understanding of helically ribbed CFRP bar bonding, development length, flexural behavior, and lap-splice mechanics in UHPC and UHPFRC matrices, providing crucial insights for enhancing structural safety and design efficiency. He has conducted extensive research on the residual bond behavior of CFRP and steel reinforcements after elevated-temperature exposure, contributing to improved fire-resilience strategies for modern infrastructure. Dr. Yoo’s research portfolio further includes development of smart strengthening techniques for fire-damaged concrete structures using hybrid FRP bars and advanced cementitious composites, alongside major contributions to CNT-reinforced lightweight high-strength concrete, DfMA-based modular bridge systems, and electrically conductive concretes for EMP protection. His publications in high-impact journals highlight innovative findings on microstructural enhancement, creep reduction, and structural performance gains enabled by CNT and FRP technologies. Through participation in multiple national research programs, he has advanced solutions for zero-corrosion CFRP reinforcement, sustainable shelter-in-place systems, and next-generation composite materials. His achievements, supported by multiple awards for outstanding papers and research excellence, demonstrate his leadership in developing resilient, high-performance FRP-integrated structural systems.

Profile:  ORCID  |  Google Scholar

Featured Publications

  • Yoo, S. J., Hong, S. H., & Yoon, Y. S. (2023). Bonding behavior and prediction of helically ribbed CFRP bar embedded in ultra-high-performance concrete (UHPC). Case Studies in Construction Materials, 19, e02253.

  • Yoo, S. J., Kim, Y. H., Yuan, T. F., & Yoon, Y. S. (2022). Evaluation of residual bond behavior of CFRP and steel bars embedded in UHPC after exposure to elevated temperature. Journal of Building Engineering, 56, 104768.

  • Hong, S. H., Choi, J. S., Yoo, S. J., Yoo, D. Y., & Yoon, Y. S. (2024). Reinforcing effect of CNT on the microstructure and creep properties of high-strength lightweight concrete. Construction and Building Materials, 428, 136294.

  • Yoo, S. J., Hong, S. H., Yoo, D. Y., & Yoon, Y. S. (2024). Flexural bond behavior and development length of ribbed CFRP bars in UHPFRC. Cement and Concrete Composites, 146, 105403.

  • Hong, S. H., Choi, J. S., Yoo, S. J., & Yoon, Y. S. (2023). Structural benefits of using carbon nanotube reinforced high-strength lightweight concrete beams. Developments in the Built Environment, 16, 100234.

Lysa Benaddache | Civil Engineering | Best Researcher Award

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Mrs. Lysa Benaddache | Civil Engineering | Best Researcher Award

Mrs. Lysa Benaddache | University Of Bordj Bou Arreridj | Algeria

Lysa Benaddache is a PhD student jointly affiliated with the LIMEEDD Laboratory, Department of Civil Engineering, Mohamed El-Bachir El-Ibrahimi University of Bordj Bou Arreridj in Algeria, and the L2MGC Laboratory at CY Cergy Paris Université in France. She holds a Master’s degree in Hydraulic Constructions and Developments and is currently engaged in doctoral research focusing on the development of sustainable eco-composite materials for the repair and strengthening of concrete structures under the effects of climate change. she has also served as a part-time lecturer, contributing to academic teaching and the supervision of final-year projects. Her research integrates areas such as reinforced concrete corrosion, eco-material design, and geopolymer technology aimed at sustainable structural repair. With an h-index of 3 on Scopus and seven published journal articles, her scientific contributions emphasize the use of natural fibers, industrial waste, and biowaste in developing eco-friendly alternatives to synthetic composites. Her studies demonstrate that certain natural fibers can match or even surpass the mechanical properties of traditional glass fibers, enhancing structural durability and sustainability. She is an active member of both the LIMEEDD and L2MGC laboratories, collaborating on innovative research in fiber-reinforced eco-composites, particularly focusing on optimizing date palm fiber treatment to improve mechanical performance and environmental resilience. Dedicated to advancing sustainable construction materials, Lysa Benaddache’s research contributes significantly to eco-innovation and the future of resilient infrastructure systems.

Profile:  ScopusGoogle Scholar

Featured Publications

Benaddache, L., Belkadi, A. A., Berkouche, A., Hadzima-Nyarko, M., et al. (2025). Modeling and optimization for the combined valorization of calcined sediments and ground blast-furnace slag in eco-mortar formulations: Rheological, mechanical, microstructural, and environmental assessments. Structures.

Benaddache, L., Belkadi, A. A., Berkouche, A., Aggoun, S., et al. (2025). Advancing structural flexural reinforcement with natural and synthetic fiber composites: Optimization of EBR and EBROG methods supported by DIC. Structures.

Berkouche, A., Belkadi, A. A., Benaddache, L., Aggoun, S., et al. (2025). Enhancing physical, mechanical, and durability properties of slag-based geopolymers through ceramic waste incorporation: A comprehensive optimization study. Journal of the Taiwan Institute of Chemical Engineers.

Benaddache, L., Belkadi, A. A., Berkouche, A., Amziane, S., Alomayri, T., Achour, Y., & Benammar, A. (2024). Experimental optimization of low-carbon cellular foam geopolymers incorporating crushed stone sand and flax fiber using central composite design. Iranian Journal of Science and Technology, Transactions of Civil Engineering, 4, 3999–4019.

Benaddache, L., Belkadi, A. A., Kessal, O., Tayebi, T., & Aggoun, S. (2024). Comparative study on externally bonded heat-treated jute and glass fiber reinforcement for repair of pre-cracked high performance concrete beams.