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)

Yaoqing Gong – Structural Engineering – Best Researcher Award

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Yaoqing Gong - Structural Engineering - Best Researcher Award

Henan Polytechnic University - China

AUTHOR PROFILE

SCOPUS
ORCID

SUMMARY

Yaoqing Gong is a distinguished academic in civil and structural engineering, currently serving as Chair Professor at Henan Polytechnic University. With over four decades of teaching, research, and engineering practice, the expertise encompasses semi-analytical structural analysis, finite element modeling, and torsional analysis of complex structures. Editorial roles, committee memberships, and national-level research projects illustrate a strong reputation in academia. Recognized by leading institutions in China, including the Ministry of Education and National Natural Science Foundation, the work influences tall building mechanics and computational analysis. Extensive publications and involvement in conference proceedings highlight an active presence in both theoretical and applied engineering domains.

EDUCATION

Completed a Ph.D. in Civil Engineering at Tsinghua University, renowned for engineering excellence. Previously earned a Master’s degree in Mechanical Engineering from Huazhong University of Science and Technology and a Bachelor’s degree from Ningxia University. The academic progression reflects a deep foundation in engineering sciences, transitioning from mechanical to civil specializations. The multidisciplinary training has significantly shaped advanced research contributions in structural mechanics, particularly in analyzing super-tall buildings and complex beam structures. The educational journey through top-tier Chinese institutions has laid the groundwork for a highly productive academic and research career across decades in civil infrastructure development and modeling.

PROFESSIONAL EXPERIENCE

Began academic career as Assistant Lecturer at Ningxia University, progressing through Lecturer, Associate Professor, and Professor roles from 1981 to 2001. Since 2001, appointed as Chair Professor at Henan Polytechnic University, leading major initiatives in structural engineering. Held several key academic responsibilities, contributing to curriculum design and research mentorship. A strong connection with national academic bodies such as the Ministry of Education and NSF of China has ensured relevance and impact in teaching and applied research. Professional duties have also extended to evaluating high-level research proposals and participating in national engineering education committees, reflecting trust and leadership in the field.

RESEARCH INTEREST

Core research interests include semi-analytical methods for analyzing dynamic loads on super-tall buildings and long-span bridges, torsional behavior of noncircular beam sections, and structural interactions with elastic subgrades. Work is heavily focused on theoretical mechanics, generalized-area-coordinate systems, and conforming finite element formulations. Special emphasis is placed on dynamic load modeling and the interaction between foundation and superstructures, particularly under spatial or multi-directional loading. Research bridges practical civil infrastructure challenges with computational mechanics innovation, advancing knowledge in constrained torsion and spatial vibration of complex geometries. Integration of analytical theory and real-world applications characterizes all research endeavors and academic outputs.

AWARD AND HONOR

Honored with roles that reflect academic prestige, including Editorial Board Membership in the Journal of Engineering Mechanics (Chinese) and Committee Member of the Mechanics Instruction Committee, Ministry of Education, China. Selected as a referee for high-impact national research proposals under the Department of Engineering & Material Science, NSF of China. Contributions to national research projects and leadership in university-affiliated foundations also serve as testimony to recognition by peers. The ability to influence educational and research standards at national levels is a distinguishing achievement. These roles underscore trust, influence, and merit across China’s academic and engineering science communities.

RESEARCH SKILL

Expert in developing semi-analytical and finite element models for structural analysis under dynamic and complex boundary conditions. Advanced in formulating generalized conforming finite elements and utilizing generalized-area-coordinate systems. Skilled in solving torsional behavior for constrained, variable thickness beams with arbitrary noncircular shapes. Familiar with both theoretical development and application to large-scale infrastructure such as super-tall buildings and bridges. Possesses hands-on design experience, including work with steel tower structures for astronomical observatories. Capable of integrating analytical theory with field application, contributing both to academia and practical engineering. Strong background in mathematical modeling, ODE solvers, and high-performance structural analysis.

PUBLICATIONS TOP NOTED

Published in prestigious journals such as Composite Structures, Engineering Structures, European Journal of Mechanics/A Solids, and MethodsX. Key contributions include innovative constrained torsional analysis, theories for stocky beams with noncircular cross-sections, and finite element formulations for thick plate-shell elements. Authored books like “Structural Mechanics” and “Tall Building Structures on Elastic Subgrade,” which serve as foundational texts in Chinese structural engineering education. Presented work at global conferences including the World Congress on Computational Mechanics. Collaborated with notable researchers on interdisciplinary projects, ensuring international visibility. Research outputs continue to shape methodologies used in modern civil engineering and computational structural mechanics.

Title: Composite stocky box girders of variable thickness in high-support expressways: Constrained torsional analysis
Authors: [Not specified]
Journal: Engineering Structures (2021)

Title: An innovative method for surmounting the constrained torsional problems of stocky beams with arbitrary noncircular cross-sectional shapes and with arbitrary elastic material properties
Authors: [Not specified]
Journal: MethodsX (2021)

Title: The torsional centre position of stocky beams with arbitrary noncircular cross-sectional shapes and with arbitrary elastic material properties
Authors: [Not specified]
Journal: European Journal of Mechanics A: Solids (2021)

CONCLUSION

Yaoqing Gong’s contributions span theoretical development, practical design, high-level academic mentorship, and national-level advisory roles. Strong expertise in civil and structural engineering mechanics is demonstrated through sustained publications, impactful research funding, and leadership roles within Chinese engineering education. The emphasis on semi-analytical methods and computational mechanics provides critical solutions for modern engineering problems such as super-tall structures, complex torsional analysis, and elastic subgrade interaction. Through integration of teaching, research, and applied science, continues to influence both academic frameworks and infrastructure practices. The profile stands as a model of excellence in civil engineering innovation, research integrity, and academic leadership.

Lewis John Gooch – Structural Engineering – Best Researcher Award

Published on by Civil Engineering Awards

Lewis John Gooch - Structural Engineering - Best Researcher Award

The University of Newcastle - Australia

AUTHOR PROFILE

SCOPUS
ORCID
GOOGLE SCHOLAR

SUMMARY

Lewis John Gooch is a dedicated civil engineer and postdoctoral research associate specializing in structural reliability and masonry design. With academic and professional experience in seismic performance analysis, numerical modelling, and experimental mechanics, Lewis contributes to advancing safer, more resilient infrastructure. His work intersects engineering theory, laboratory experimentation, and practical design, producing high-impact research publications and real-world engineering solutions. Recognized with numerous academic and industry awards, Lewis has established strong collaborative ties with research institutions and industry stakeholders. His career reflects a strong commitment to engineering excellence, scholarly advancement, and impactful industry engagement within the Australian civil and structural engineering landscape.

EDUCATION

Lewis completed his Ph.D. in Civil Engineering at The University of Newcastle, focusing on stochastic assessment and structural reliability of unreinforced masonry walls under shear loading. Prior to this, he earned a Bachelor of Civil Engineering (Honours) with University and Faculty Medals, demonstrating exceptional academic performance. He also pursued the Academic Career Preparation Pathway, gaining university teaching competencies. These educational milestones have equipped him with expertise in structural mechanics, probabilistic modelling, and engineering pedagogy, forming a strong foundation for his academic and professional career. His academic training continues to inform his research into innovative and reliable construction design methodologies.

PROFESSIONAL EXPERIENCE

Lewis currently serves as a Postdoctoral Research Associate at the University of Technology Sydney, leading efforts to calibrate masonry design standards under ARC Discovery Project DP220102758. Concurrently, at The University of Newcastle, he contributes to infrastructure performance through digital image correlation and laboratory test development. Formerly a structural engineer at Lindsay Dynan, he managed complex assessments of bridges, concrete structures, and scaffolding systems. These roles demonstrate a seamless transition from professional engineering to high-level research, with responsibilities including supervision of students, development of experimental methods, and national code contributions—showcasing a rare blend of academic insight and practical engineering skill.

RESEARCH INTEREST

Lewis's research explores the intersection of structural engineering, material behaviour, and probabilistic modelling. His primary focus is on the performance of unreinforced masonry (URM) structures under seismic and wind loads. He develops stochastic models to simulate spatial variability and uses finite element analysis to evaluate structural response. Additionally, he investigates material uncertainties, structural reliability, and safety factor calibration within Australian design codes. His interests extend to experimental validation using high-resolution testing methods. Lewis aims to reduce risk in civil infrastructure through improved understanding of material properties and modelling uncertainties—providing engineering solutions backed by scientific rigour and innovation.

AWARD AND HONOR

Lewis has earned multiple prestigious accolades for academic and industry excellence. These include the University Medal and Faculty Medal from The University of Newcastle, along with consistent recognition on the Dean’s Merit and Commendation Lists. He has received industry awards such as the Engineers Australia Prize, Douglas Partners Prize for Applied Geotechnics, and Steel Reinforcement Institute of Australia Award. These distinctions highlight his exceptional performance in both technical proficiency and academic scholarship. His awards reflect a career marked by excellence in geotechnics, water engineering, structural analysis, and masonry design, positioning him as a rising leader in civil engineering research.

RESEARCH SKILL

Lewis demonstrates expertise in high-resolution digital image correlation, finite element modelling, and stochastic analysis of masonry structures. He is proficient in developing and validating experimental testing methods, including shear and tensile strength characterization. He applies statistical models to quantify material variability and risk in structural performance, contributing to design standard calibration. His experience in software tools for structural simulation and data interpretation supports comprehensive model validation. Furthermore, he provides supervision and technical mentorship across undergraduate and postgraduate levels. His research skillset reflects a deep integration of theoretical understanding, practical experimentation, and computational engineering, essential for advancing structural reliability.

PUBLICATIONS TOP NOTED

Lewis has authored influential journal articles and conference papers in leading engineering venues. Noteworthy publications include studies on mortar friction coefficients, URM shear wall behaviour, and statistical assessment of clay brick masonry—appearing in journals like Construction and Building Materials, Journal of Structural Engineering, and Bulletin of Earthquake Engineering. His work is widely cited for advancing knowledge in masonry design, model uncertainty, and stochastic structural analysis. He has also presented internationally on life-cycle monitoring and structural safety. His contributions play a critical role in refining seismic design methods and improving structural resilience, bridging academic research with engineering practice.

Title: Accuracy of stochastic finite element analyses for the safety assessment of unreinforced masonry shear walls
Authors: Lewis J. Gooch, Mark G. Stewart, M. J. Masia
Journal: Civil Engineering and Environmental Systems

Title: Experimental characterisation of the friction coefficient of mortar bed joints in clay-brick masonry
Authors: Lewis J. Gooch, Mark J. Masia, Mark G. Stewart, Michele Spadari
Journal: Construction and Building Materials

Title: Experimental Testing of Unreinforced Masonry Shear Walls and Comparison with Nominal Capacity Predictions
Authors: Lewis J. Gooch, Mark J. Masia, Mark G. Stewart, Md. Akhtar Hossain
Journal: Journal of Structural Engineering

Title: Model accuracy for the prediction of unreinforced clay brick masonry shear wall resistance
Authors: Lewis J. Gooch, Mark G. Stewart, Mark J. Masia
Journal: Bulletin of Earthquake Engineering

Title: Spatial Correlation of Flexural Tensile Bond Strength in Unreinforced Masonry Walls
Authors: Lewis J. Gooch, M. J. Masia, Mark G. Stewart, C. Collard
Journal: Lecture Notes in Civil Engineering

Title: Statistical assessment of tensile and shear properties of unreinforced clay brick masonry
Authors: Lewis J. Gooch, Mark J. Masia, Mark G. Stewart, Chee Yin Lam
Journal: Construction and Building Materials

CONCLUSION

Lewis John Gooch exemplifies the qualities of a modern structural engineering researcher: analytically rigorous, experimentally adept, and industry-aware. His commitment to enhancing infrastructure resilience through advanced modelling and testing informs both academic discourse and practical design. Recognized for academic excellence and industry contribution, Lewis's career continues to evolve through impactful research, scholarly publications, and teaching. With his focus on masonry structures and structural reliability, he contributes meaningfully to national design standards and global understanding of risk-informed engineering. His trajectory highlights a promising future as a thought leader in civil engineering innovation and infrastructure safety assessment.