Fuat Aras | Structural Engineering | Research Excellence in Civil and Environmental Engineering Award

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Prof. Fuat Aras | Structural Engineering | Research Excellence in Civil and Environmental Engineering Award

Istanbul Medeniyet University | Turkey

Prof. Fuat Aras is a distinguished civil engineer whose academic and research trajectory demonstrates substantial contributions to structural dynamics, earthquake engineering, and the protection of historical and modern infrastructures. With extensive experience as Professor in the Civil Engineering Department at Istanbul Medeniyet University, he has built a strong research portfolio grounded in experimental and numerical analyses of reinforced concrete and masonry structures, dynamic characterization, structural health monitoring, and seismic retrofitting. His scholarly accomplishments include numerous SCI/SCIE-indexed journal publications, books, and international conference papers, reflecting a consistent commitment to advancing global knowledge in earthquake-resistant design and the preservation of cultural heritage structures. Prof. Aras has coordinated several national research projects funded by TUBITAK, focusing on innovative technologies for improving building performance, dynamic behavior evaluation, and damage assessment, while also contributing to major European Union–supported initiatives on seismic protection. He has supervised multiple graduate theses on structural monitoring, retrofitting strategies, and seismic performance, indicating strong mentorship and academic leadership. His long-standing collaborations with national and international institutions, including partnerships with researchers in Türkiye, Europe, and the United States, highlight his interdisciplinary and global impact. In addition to his research excellence, he has held key administrative roles such as department chair and vice dean, strengthening institutional development and academic governance. His body of work has supported safer community infrastructures by providing evidence-based insights into building behavior, seismic vulnerabilities, and preservation strategies, thereby contributing significantly to societal resilience. With extensive teaching experience in core structural engineering courses and expertise in advanced analytical tools, Prof. Aras continues to shape the next generation of engineers while expanding research frontiers in structural dynamics and earthquake engineering, positioning him as a highly influential figure with strong future potential for further impact in his field.

Profile: Google Scholar | ORCID
Publications

Aras, F., Krstevska, L., Altay, G., & Tashkov, L. (2011). Experimental and numerical modal analyses of a historical masonry palace. Construction and Building Materials, 25(1), 81–91.

Namli, M., & Aras, F. (2020). Investigation of effects of dynamic loads in metro tunnels during construction and operation on existing buildings. Arabian Journal of Geosciences, 13(11), 424.

Aras, F., & Altay, G. (2015). Investigation of mechanical properties of masonry in historic buildings. Građevinar, 67(5),

Aras, F., & Altay, G. (2015). Seismic evaluation and structural control of the historical Beylerbeyi Palace. Structural Control and Health Monitoring, 22(2), 347–364.

Aras, F., & Düzci, E. (2018). Seismic performance of traditional stone masonry dwellings under Çanakkale seismic sequences. Journal of Performance of Constructed Facilities, 32(4), 04018029.

Ahmad Nassef | Structural Engineering | Best Researcher Award

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Assoc. Prof. Dr. Ahmad Nassef | Structural Engineering | Best Researcher Award

Associate professor | University of Buraimi | Oman

Assoc. Prof. Dr. Ahmad Salah Edeen Nassef is an accomplished Associate Professor of Structural Engineering at Helwan University, Egypt, and the University of Buraimi, Oman, where he also served as Acting Dean and Assistant Dean of the College of Engineering. With over two decades of academic and professional experience, his expertise spans structural analysis, reinforced concrete and steel design, nonlinear structural behavior, and sustainability in construction materials. He earned his Ph.D. and M.Sc. in Structural Engineering from Cairo University and a B.Sc. in Civil Engineering from Helwan University. Dr. Nassef has authored numerous publications in international journals and conferences, covering topics such as buckling of columns, nonlinear damage mechanics, composite structures, and eco-friendly concrete using palm tree and medical waste materials. His research contributions, reflected in a growing citation record, demonstrate his global engagement and innovation in sustainable structural systems. He has led and mentored multiple funded research projects supported by institutions such as the Ministry of Higher Education, Research, and Innovation (MOHERI) of Oman and Najran University, addressing practical engineering challenges and advancing materials recycling and durability enhancement. Beyond research, Dr. Nassef has been deeply involved in academic leadership, serving as Chair of Research and Ethics Committees, ABET and OAAA accreditation coordinator, and quality assurance leader for civil engineering programs. His scholarly excellence has been recognized with multiple awards, including the University of Buraimi’s Scholarship and Teaching Excellence Awards (2022, 2023) and Best Student Research Paper Awards at national symposiums. His extensive collaborations and mentorship have significantly contributed to capacity building and research culture in the Middle East. Through his sustained efforts in integrating innovation, sustainability, and quality education, Dr. Nassef continues to make a notable global impact in civil and structural engineering research and higher education.

Profile: Scopus | Google Scholar
Publications:

Nassef, A. S. E. (2015). Fibonacci sequence and golden ratio in new formula of predicting cracks propagation in reinforced concrete tie. International Journal of Damage Mechanics, 24(8), 1214–1226. 
(Cited by: 5)

Nassef, A. S. E., & Dahim, M. A. (2016). New bi-modular material approach to buckling problem of reinforced concrete columns. [Journal name unavailable]. (Cited by: 6)

Nassef, A. S. E., Nassar, M. M., & El-Refaee, M. M. (2019). Dynamic response of Timoshenko beam resting on nonlinear Pasternak foundation carrying sprung masses. Iranian Journal of Science and Technology, Transactions of Mechanical Engineering. 
(Cited by: 9)

Nassef, A. S. E., Al-Maqbali, K. H., & Al Naqabi, S. M. (2021). Effects of replacing cement by date palm trees wastes on concrete performance. Proceedings of the International Structural Engineering and Construction, 8(1). 
(Cited by: 5)

Nassef, A. (2022). Non-prismatic model for laterally loaded pile in granular soil resisted by ultimate lateral reaction. International Journal of Geotechnical Engineering, 16(4), 400–407. 
(Cited by: 4)

Poloju Kiran Kumar | Structural Engineering | Best Academic Researcher Award

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Dr. Poloju Kiran Kumar | Structural Engineering | Best Academic Researcher Award

Senior Lecturer | Middle East College | Oman

Dr. Poloju Kiran Kumar is a distinguished researcher and academician in civil and environmental engineering, presently serving as Senior Lecturer at Middle East College, Muscat, Oman, and Committee Member of the Institution of Civil Engineers (ICE), Oman region. With over thirteen years of academic and research experience, his expertise encompasses structural engineering, sustainable construction materials, and advanced geopolymer concrete technology. Dr. Kiran has authored more than 80 research papers in Web of Science and Scopus-indexed journals and contributed eight book chapters published by Springer, Taylor & Francis, and Nova Publishers. His research achievements include five patents in India and Oman focusing on innovative sustainable concrete materials and artificial intelligence applications in structural performance analysis. He has successfully completed four externally funded research projects worth 16,000 OMR from The Research Council of Oman and leads collaborative projects with Prince Sattam bin Abdulaziz University, Saudi Arabia. His scholarly influence is reflected through over 250 Google Scholar citations with an h-index of 12. Dr. Kiran’s academic leadership is evident in his role in program accreditation, quality assurance, and development of modern teaching pedagogies integrating digital tools. His commitment to sustainable construction and community engagement has earned multiple accolades, including four Best Academic Staff Awards, the INSO Young Scientist Award (2022), and recognition as ICE Oman’s Committee Member (2025). A Chartered Engineer and Fellow of the Higher Education Academy (UK), Dr. Kiran has delivered numerous keynote lectures and workshops across Oman, India, and beyond on geopolymer concrete, sustainable infrastructure, and pedagogical innovation. His research contributes significantly to the advancement of low-carbon construction technologies, enhancing environmental resilience and promoting sustainable development in alignment with global engineering goals.

Profile: Scopus | Google Scholar
Publications:

Poloju, R. K. M. K., & Anil, V. (2017). Properties of concrete as influenced by shape and texture of fine aggregate. American Journal of Applied Scientific Research, 3(3), 28–36.
(Cited by: 22)

Poloju, K. K., & Srinivasu, K. (2021). Impact of GGBS and strength ratio on mechanical properties of geopolymer concrete under ambient curing and oven curing. Materials Today: Proceedings, 42, 962–968. 
(Cited by: 60)

Rollakanti, C. R., Prasad, C. V. S. R., Poloju, K. K., Al Muharbi, N. M. J., & Arun, Y. V. (2021). An experimental investigation on mechanical properties of concrete by partial replacement of cement with wood ash and fine sea shell powder. Materials Today: Proceedings, 43, 1325–1330. 
(Cited by: 56)

Poloju, V. R. K. K., & Naidu, [First initial unavailable]. (2022). New method of data collection using the Kobo Toolbox. Journal of Positive School Psychology, 1527–1535.
(Cited by: 39)

Al Abri, S. A. S., Rollakanti, C. R., Poloju, K. K., & Joe, A. (2022). Experimental study on mechanical properties of concrete by partial replacement of cement with eggshell powder for sustainable construction. Materials Today: Proceedings, 65, 1660–1665. 
(Cited by: 25)

Ahmed A. Kader | Materials Science and Engineering | Excellence in Research Award

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Assoc. Prof. Dr. Ahmed A. Kader | Materials Science and Engineering | Excellence in Research Award

Associate Prof | Giza Engineering Institute | Egypt

Assoc. Prof. Dr. Ahmed A. Kader’s research field encompasses a wide spectrum of structural and civil engineering applications, with an emphasis on sustainable materials, structural performance, and innovative construction technologies. His extensive project experience includes consulting and managing large-scale civil infrastructure projects, serving as a Construction Manager and Head of Structural Design Offices for various consultancy firms in Egypt and Saudi Arabia. His expertise lies in the design and analysis of reinforced concrete, foundation engineering, fluid mechanics, and hydrology, coupled with advanced computational tools such as SAP2000, ETABS, SAFE, and BIM modeling systems. His research interests center around the development and optimization of eco-friendly and high-performance materials, particularly geopolymer concrete incorporating industrial by-products like red-mud and zeolite, and the use of alkali-activated binders to enhance mechanical and durability properties. Dr. Kader’s published works reflect his dedication to addressing global environmental challenges through green engineering approaches, including the utilization of recycled aggregates, volcanic tuff, and banana fiber in concrete composites. His projects explore the structural performance of modern construction systems such as precast insulated panels and fiber-reinforced concrete, aiming to improve energy efficiency, load resistance, and long-term durability. Through experimental studies, numerical modeling, and field applications, he contributes to advancements in sustainable infrastructure, construction waste recycling, and smart material integration. His research and consulting collaborations with engineering institutions and industry partners continue to bridge the gap between academic innovation and practical implementation, underscoring his commitment to advancing the civil engineering field through scientific inquiry, sustainable design, and technical excellence.

Profile: Google Scholar | ORCID
Featured Publications:

Attia, M. M., Al Sayed, A., Tayeh, B. A., & Shawky, S. M. M. (2022). Banana agriculture waste as eco-friendly material in fibre-reinforced concrete: An experimental study. Advances in Concrete Construction, 14, 355–368.

Edris, W. F., Abdelkader, S., Salama, A. H. E., & Al Sayed, A. (2021). Concrete behaviour with volcanic tuff inclusion. Civil Engineering and Architecture, 9, 1434–1441.

Shaaban, M., Edris, W. F., Odah, E., Ezz, M. S., & Al-Sayed, A. (2023). A green way of producing high strength concrete utilizing recycled concrete. Civil Engineering Journal, 9(10), 2467–2485.

Edris, W. F., Elbialy, S., El-Zohairy, A., Soliman, A. M., Shawky, S. M. M., Selouma, T. I., ... (2024). Examining mechanical property differences in concrete with natural and synthetic fiber additives. Journal of Composites Science, 8(5), 167.

Al Sayed, A. A. K. A., Al-Waked, Q. F., Shawky, S. M. M., Al-jabali, H. M., & Edris, W. F. (2023). Effect of alkali activated limestone-silica fume blended precursor on performance enhancement of recycled aggregate concrete. Case Studies in Construction Materials, 19, e02661.

Xiao Jiayu | Structural Engineering | Best Researcher Award

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Xiao Jiayu | Structural Engineering | Best Researcher Award

Central South University of Forestry and Technology | China

Xiao Jiayu is an emerging researcher from Central South University of Forestry and Technology, specializing in the interdisciplinary fields of landscape architecture and civil and hydraulic engineering. She earned her Bachelor’s degree in Landscape Architecture in 2024, ranking within the top 30% of her cohort, and is currently pursuing a Master’s degree in Civil and Hydraulic Engineering at the same institution, continuing her academic excellence with a strong research orientation. Her academic foundation integrates aesthetic, ecological, and structural design principles, reflected through outstanding performance in subjects such as landscape engineering, environmental psychology, urban green space planning, and advanced concrete and steel structure theories. Demonstrating exceptional analytical and technical abilities, she has developed a keen interest in sustainable design, structural safety, and green infrastructure systems that contribute to environmental resilience and urban livability. Her current research direction focuses on the integration of engineering precision with ecological sensitivity, aiming to advance innovative solutions for sustainable urban development and landscape restoration. Xiao Jiayu’s strong command of design software, numerical analysis, and experimental techniques enables her to bridge creative design with scientific rigor effectively. Throughout her academic journey, she has exhibited strong teamwork and leadership skills through university projects, collaborative design workshops, and interdisciplinary studies. Her academic pursuits reflect a deep commitment to fostering harmony between built environments and natural ecosystems, highlighting her potential to make significant contributions to sustainable construction and landscape innovation. With a growing academic profile and dedication to continuous learning, she represents the new generation of scholars poised to shape the future of civil engineering and environmental design through research-driven, socially responsible, and technologically informed approaches.

Profile: ORCID
Featured Publications:

Yuan, J., Xiao, J., & Huang, D. (2025, December). Experimental research on bond behavior of high-strength reinforcement in unconfined fly ash-based geopolymer concrete. Case Studies in Construction Materials.

Changbai Wang | Structural Engineering | Best Researcher Award

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Dr. Changbai Wang | Structural Engineering | Best Researcher Award

Vice-Dean | Anhui University of Science and Technology | China

Dr. Changbai Wang, affiliated with Anhui University of Science and Technology, Huainan, China, is a distinguished researcher recognized for his significant contributions to the field of construction materials and sustainable concrete technologies. With a robust publication record of 20 scholarly documents, his research has achieved over 343 citations across 326 documents, reflecting a notable h-index of 10, underscoring the consistent quality and influence of his academic work. Dr. Wang’s research primarily focuses on high-performance concrete (HPC), internal curing mechanisms, and the innovative utilization of industrial by-products, particularly coal gangue aggregates, to enhance the sustainability and performance of civil engineering materials. His recent works, such as studies on pore-regulated coal aggregates and self-compacting tunnel concrete, demonstrate his commitment to advancing environmentally responsible construction practices. Collaborating with over 40 co-authors, he has fostered interdisciplinary partnerships that bridge material science, civil engineering, and environmental sustainability. Through his extensive research collaborations, Dr. Wang contributes to the global discourse on low-carbon construction, emphasizing circular economy principles and resource optimization in infrastructure development. His scholarly influence extends beyond academia, as his findings have practical implications for industries aiming to reduce ecological footprints while maintaining material performance. The societal impact of his work lies in promoting sustainable material innovation aligned with modern infrastructure needs. With ongoing projects and emerging studies in high-performance concrete applications, Dr. Wang demonstrates strong potential for further breakthroughs in green construction materials and structural durability research. His academic trajectory and commitment to addressing global environmental challenges position him as a key contributor to the future of sustainable construction and materials engineering.

Profile: Scopus | ORCID
Featured Publications:

  • Updated internal curing for HPC using pore-regulated coal aggregates. Case Studies in Construction Materials.

  • Internal curing for tunnel self-compacting concrete using pre-soaked coal gangue: A promising way for spot utilization of coal gangue. Iranian Journal of Science and Technology Transactions of Civil Engineering.

Saad A. A. Jabir | Structural Health Monitoring | Research Excellence in Civil and Environmental Engineering Award

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Saad A. A. Jabir | Structural Health Monitoring | Research Excellence in Civil and Environmental Engineering Award

CEO | Nur Engineering GmbH | Germany

Saad A. A. Jabir’s research focuses on advancing condition monitoring and structural health assessment within civil engineering, emphasizing innovative sensor-based approaches for real-time evaluation of infrastructure performance. His primary contributions are in the development and application of thick-film ceramic sensors for measuring the strength and stability of civil structures. Jabir’s work demonstrates the potential of these sensors in providing accurate, durable, and responsive measurements that enhance the reliability and safety of infrastructure systems. Through his publications, he explores the integration of sensing technology into civil structures, enabling continuous monitoring that aids in preventive maintenance and early fault detection. His research also intersects materials science and measurement engineering, with attention to improving sensor materials’ thermal and mechanical resilience for field applications. By addressing challenges such as environmental variability and long-term stability of sensor outputs, Jabir contributes to making structural monitoring systems more adaptive and cost-effective. His studies have significant implications for modern smart infrastructure and sustainable construction practices, providing valuable insights into how sensor technologies can be scaled for large-scale engineering projects. His collaborative work reflects an interdisciplinary approach combining electrical engineering, materials research, and civil infrastructure monitoring to create robust diagnostic systems for critical assets. Saad A. A. Jabir’s research output, though concise, holds impactful applications for modern infrastructure management and reliability improvement in engineering systems. 60 Citations 3 Documents 2 h-index

Profile: Scopus
Featured Publications:

Condition monitoring of the strength and stability of civil structures using thick film ceramic sensors. (2013). Measurement: Journal of the International Measurement Confederation.

Zhou Ji | FRP reinforced concrete structure | Best Researcher Award

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Zhou Ji | FRP Reinforced Concrete Structure | Best Researcher Award

Associate Professor | Nanjing Forestry University | China

Zhou Ji is a dedicated civil engineering researcher specializing in steel–concrete composite structures and marine or offshore concrete systems, with extensive academic and practical expertise in structural performance and durability. As a doctoral researcher at Guangxi University under Professor Zongping Chen, Zhou has contributed significantly to the understanding of mechanical behaviors, bond characteristics, and seismic performance of advanced composite materials. Zhou has led one Guangxi postgraduate education innovation project and participated in six national and provincial-level research programs focusing on areas such as high-temperature damage assessment, corrosion-resistant marine concrete, and long-lifespan transport hub structures. The research has resulted in 9 SCI-indexed papers and 10 EI-indexed papers as the first author, including publications in high-impact journals like Engineering Structures, Construction and Building Materials, and Journal of Composites for Construction-ASCE. Zhou’s studies on CFRP-steel composite bars in coral sea-sand seawater concrete have provided key insights into bond behavior, structural strength, and post-fire performance, contributing to sustainable marine construction. In addition to academic publications, Zhou has secured four national patents and participated in developing a Guangxi provincial standard. Recognition of excellence includes numerous national and provincial scholarships and awards, such as the Liu Huixian Earthquake Engineering Award and multiple National Scholarship distinctions. The research achievements reflect a deep commitment to advancing composite structural technologies that enhance resilience and sustainability in coastal infrastructure. With a strong foundation in both experimental and numerical analysis, Zhou continues to explore innovative materials and design approaches that address environmental challenges in modern civil engineering. 409 Citations, 16 Documents, and an h-index of 11

Profile: Google Scholar | Scopus | Research Gate

Chen, Z., Zhou, J., Jing, C., & Tan, Q. (2021). Mechanical behavior of spiral stirrup reinforced concrete filled square steel tubular columns under compression. Engineering Structures, 226, 111377.

Chen, Z., Xu, W., & Zhou, J. (2022). Mechanical performance of marine concrete filled CFRP–aluminum alloy tube columns under axial compression: Experiment and finite element analysis. Engineering Structures, 272, 114993.

Chen, Z., Li, S., Zhou, J., Xu, R., & Dai, S. (2022). Flexural behavior of GFRP bars reinforced seawater sea sand concrete beams exposed to marine environment: Experimental and numerical study. Construction and Building Materials, 349, 128784.

Chen, Z., Pang, Y., Xu, R., Zhou, J., & Xu, W. (2022). Mechanical performance of ocean concrete-filled circular CFRP–steel tube columns under axial compression. Journal of Constructional Steel Research, 198, 107514.

Zhou, J., Chen, Z., Chen, Y., Song, C., Li, J., & Zhong, M. (2022). Torsional behavior of steel reinforced concrete beam with welded studs: Experimental investigation. Journal of Building Engineering, 48, 103879.

Azunna Sunday | Structural Engineering | Best Researcher Award

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Mr. Azunna Sunday | Structural Engineering | Best Researcher Award

Doctoral Researcher | Housing research centre | Malaysia

Mr. Azunna Sunday Ugochukwu has established a strong professional and research background in civil and structural engineering, with notable expertise in sustainable construction materials, structural analysis, and project management. His career includes extensive work in both academic and industrial settings, where he contributed to the design and execution of major infrastructure projects such as residential complexes, university facilities, religious centers, and extensive road networks across Nigeria. At Universiti Putra Malaysia, his research has focused on innovative materials for civil engineering applications, including coconut shell, palm kernel shell, recycled bricks, granite powder, and rubberized geopolymer concrete, leading to multiple publications in reputable international journals. His scholarly contributions span experimental and review studies, addressing compressive strength, stress-strain behavior, and dynamic response of advanced concrete materials, demonstrating his capacity to integrate environmental sustainability with engineering performance. Beyond research, Azunna has engaged in professional workshops on structural modeling, design, and detailing, sharing expertise with institutions such as Federal Polytechnic Bauchi and Abubakar Tafawa Balewa University. His memberships with COREN, the Nigerian Institution of Civil Engineers, and the Nigerian Society of Engineers affirm his commitment to professional standards and development within the engineering community. With experience as an assistant structural engineer, assistant project manager, and doctoral researcher, he has consistently demonstrated versatility in applying theoretical knowledge to practical engineering challenges. His skill set includes advanced structural design software, AutoCAD, drone operation, and engineering instrumentation, underscoring his technological adaptability. The scope of his executed projects—from institutional buildings to healthcare facilities and leisure parks—highlights his versatility and capacity to manage diverse engineering assignments effectively. His growing academic output, combined with practical project delivery, positions him as a significant contributor to advancing civil engineering knowledge and practice. Engr. Azunna Sunday Ugochukwu has achieved 120 Citations, 8 Documents, and 5 h-index.

Profile: Scopus | Google Scholar | ORCID
Featured Publications:

Azunna, S. U. (2019). Compressive strength of concrete with palm kernel shell as a partial replacement for coarse aggregate. SN Applied Sciences, 1(4), 342.

Azunna, S. U., Aziz, F. N. A. A., Rashid, R. S. M., & Bakar, N. B. A. (2024). Review on the characteristic properties of crumb rubber concrete. Cleaner Materials, 12, 100237.

Azunna, S. U., Aziz, F. N. A. A., Cun, P. M., & Elhibir, M. M. O. (2019). Characterization of lightweight cement concrete with partial replacement of coconut shell fine aggregate. SN Applied Sciences, 1(6), 649.

Azunna, S. U., Aziz, F. N. A. A., Bakar, N. A., & Nasir, N. A. M. (2018). Mechanical properties of concrete with coconut shell as partial replacement of aggregates. IOP Conference Series: Materials Science and Engineering, 431(3), 032001.

Azunna, S. U., Aziz, F. N. A. B. A., Al-Ghazali, N. A., Rashid, R. S. M., & Bakar, N. A. (2024). Review on the mechanical properties of rubberized geopolymer concrete. Cleaner Materials, 11, 100225.

Pei Bida – Construction Management – Best Researcher Award

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Pei Bida | Construction Management | Best Researcher Award

Lecture | Changsha University of Science & Technology | China

Pei Bida has focused research efforts on advancing the field of civil and environmental engineering with a strong emphasis on modern methods and technologies that enhance the performance, safety, and sustainability of large-scale infrastructure systems. His primary interests include Building Information Modeling (BIM), which he employs to improve project coordination, optimize resource use, and advance the integration of digital solutions into engineering practices. A significant portion of his work is devoted to the numerical simulation of large-span bridges, where he applies computational techniques to analyze structural responses under varying conditions, thereby providing more accurate assessments of safety, serviceability, and durability. This direction in research contributes to the efficient design, construction, and maintenance of bridge systems, ensuring that they meet the increasing demands of modern transportation networks. Another key area of his expertise lies in the fatigue analysis of steel bridges, where he examines the long-term behavior of materials and structural components subjected to cyclic loading. Through such investigations, he seeks to address critical issues of degradation and performance loss, thereby extending the service life of important infrastructure while reducing maintenance costs. His research not only contributes to academic understanding but also has direct practical applications in engineering practice, offering solutions to pressing challenges faced in bridge construction and management. By integrating BIM, advanced simulations, and fatigue studies, Pei Bida is shaping a holistic approach to modern civil engineering that bridges theoretical insights with engineering applications. His contributions demonstrate a commitment to advancing safe, efficient, and technologically driven infrastructure solutions that align with the evolving needs of society. This ongoing body of work underlines his role as a significant contributor to civil engineering research, and his scholarly impact is reflected in 231 Citations by 217 documents, 23 Documents, and a 9 h-index View.

Profile: Scopus
Publications

  1. Experimental and analytical study on the flexural behavior of a novel steel-NC-UHPC composite bridge deck system. (2025).

  2. Experimental study on negative bending resistance of steel-NC-UHPC composite bridge deck. (2025).