Lutfar Rana | Building Materials | Best Researcher Award

Mr. Lutfar Rana | Building Materials | Best Researcher Award

Asst.Prof | Bangladesh Army International University of science and Technology | Bangladesh

Md. Lutfar Rahman Talukder Rana has established a growing research portfolio in Civil and Structural Engineering, focusing primarily on sustainable materials, structural resilience, and innovative concrete technologies. His professional journey as an Assistant Professor and former Head of Department reflects his expertise in managing academic and research initiatives while guiding engineering projects with real-world impact. His research projects revolve around recycled materials in construction, particularly examining the fresh and mechanical properties of concrete incorporating recycled waste glass and brick aggregates. He has contributed to high-impact Q1 journals such as Journal of Building Engineering and Construction & Building Materials, with notable studies addressing the behavior of recycled concrete, fire-damaged reinforced columns, and ferrocement strengthening techniques. Rana has also participated in international conferences, presenting work on sustainable development within civil engineering, demonstrating a consistent commitment to environmental consciousness in infrastructure development. His professional experience extends to organizing seminars like “Seismic Detailing of Reinforced Concrete Structures,” emphasizing his engagement in knowledge dissemination and technical skill development. His research interest lies in developing eco-friendly, high-performance building materials, structural retrofitting, and seismic design strategies that enhance durability and sustainability. His collaborative work with experts from BUET and MIST further supports his interdisciplinary approach and pursuit of innovation. With growing recognition, as indicated by his ResearchGate citation count (45) and continued publication in reputed outlets, Rana is contributing meaningfully to the advancement of structural and materials engineering. His future endeavors aim to optimize the integration of recycled components in concrete and explore advanced composite materials to meet global sustainability goals in the construction industry.

Profile: Scopus

Featured Publications:
Effect of waste glass on the flexural response of reinforced concrete beams containing recycled brick aggregate. Cleaner Materials.

Loannis Christodoulou | Materials Science and Engineering | Best Researcher Award

Mr. Loannis Christodoulou | Materials Science and Engineering | Best Researcher Award

PhD Candidate | National Technical University of Athens | Greece

Mr. Ioannis Christodoulou’s research activities encompass advanced studies in manufacturing technologies, additive manufacturing, and the mechanical behavior of composite materials. His current work as a researcher in the national AMOS Project focuses on the development and experimental evaluation of auxetic lattice structures designed for biomedical implants, emphasizing mechanical adaptability and biocompatibility. He has significant project experience in the modeling and optimization of high-deposition-rate 3D printing processes for amorphous materials, supported by competitive research funding. His applied engineering expertise extends to projects such as digitalizing hospital operation rooms, developing smart urban infrastructure like automated VR benches, and designing precision mechanical systems such as fabric tape winding mechanisms. His research interests lie in additive manufacturing, rapid prototyping, finite element analysis, and mechanical design automation. Christodoulou has contributed to multiple peer-reviewed publications on Fused Filament Fabrication (FFF), exploring surface roughness, geometrical accuracy, and mechanical properties of composite filaments like Nylon-Carbon Fiber and ABS-Kevlar. His investigations integrate experimental work with computational modeling, reflecting a strong commitment to improving the efficiency and performance of 3D printing systems. In parallel, his professional experience includes roles in mechanical design and optimization across industries such as interior engineering and elevator manufacturing, where he implemented CAD-based automation to enhance production workflows. He has presented his findings at numerous international conferences and has been recognized with distinctions including first place in the NASA Space Apps Challenge and the NTUA Student Innovative Paper Award. His continuing research aims to expand the practical capabilities of additive manufacturing for industrial and medical applications, promoting sustainable innovation and precision in material processing and design engineering.

Profile: Google Scholar
Featured Publications:
  • Alexopoulou, V. E., Christodoulou, I. T., & Markopoulos, A. P. (2022). Effect of printing speed and layer height on geometrical accuracy of FDM-printed resolution holes of PETG artifacts. Engineering Proceedings, 24(1), 11.

  • Christodoulou, I. T., Alexopoulou, V. E., Karkalos, N. E., Papazoglou, E. L., & Markopoulos, A. P. (2022). On the surface roughness of 3D printed parts with FDM by a low-budget commercial printer. Cutting & Tools in Technological System, 52–64.

  • Christodoulou, I. T., Alexopoulou, V. E., & Markopoulos, A. P. (2024). An experimental investigation of the mechanical properties of fused filament fabricated nylon-carbon fiber composites. Cutting & Tools in Technological System, 148–167.

  • Alexopoulou, V. E., Christodoulou, I. T., & Markopoulos, A. P. (2024). Investigation of printing speed impact on the printing accuracy of fused filament fabrication (FFF) ABS artefacts. Manufacturing Technology, 24, 333–337.

  • Christodoulou, I., Alexopoulou, V., & Markopoulos, A. P. (2023). Study and development of a high-speed fused filament fabrication 3D printer. In 2023 8th South-East Europe Design Automation, Computer Engineering, Computer Applications Conference (SEE-Conference).

Su Li | Sustainable Development | Best Researcher Award

Prof. Su Li | Sustainable Development | Best Researcher Award

Professor | Northeastern University | China

Prof. Su Li, an accomplished Associate Professor and Doctoral Supervisor at the Institute of Advanced Optoelectronic Functional Materials and Devices, Northeastern University at Qinhuangdao, is recognized for her pioneering contributions to intelligent optoelectronic materials and self-powered sensing technologies. She earned her Ph.D. in Materials Physics and Chemistry from Sun Yat-sen University and her B.Sc. in Applied Chemistry from Guizhou University. Dr. Li’s research focuses on novel optoelectronic functional materials and devices, intelligent sensing and detection, and information fusion and system integration methods. Her innovative work in triboelectrification-induced electroluminescence has led to the development of high-performance, miniaturized, and energy-efficient optoelectronic systems with broad applications in artificial perception, human–machine interaction, and environmental monitoring. As first or corresponding author, she has published over 30 high-impact papers in top-tier international journals, including Science Advances, Advanced Functional Materials, Nano Energy, and ACS Nano, and her research is widely cited within the materials science and nanotechnology communities. She holds more than 20 patents and software copyrights, underscoring her commitment to technological innovation and societal impact. Dr. Li has delivered over 10 invited talks at domestic and international conferences and has successfully led multiple National Natural Science Foundation of China (NSFC) projects, including both general and youth programs, focusing on next-generation self-powered and visual sensing systems. Her interdisciplinary collaborations with leading scientists such as Zhong Lin Wang and Yunlong Zi have advanced global progress in mechanical–optical–electrical energy conversion and multimodal sensing integration. As a Senior Member of the Chinese Association of Automation and an active member of several national scientific societies, Dr. Su Li continues to bridge scientific excellence and real-world application, contributing to the advancement of sustainable, intelligent, and high-efficiency optoelectronic technologies.

Profile: Scopus
Featured Publications:
  • Spiral electrodes-enhanced triboelectrification-induced electroluminescence in nanocellulose composites for self-powered visualized acoustic sensing. Polymer Composites.

  • Photonic film based on triboelectrification-induced electroluminescence for self-powered visualization and handwriting recognition.

  • High-brightness and high-resolution triboelectrification-induced electroluminescence skin for photonic imaging and information interaction. Advanced Functional Materials.

Li Su pioneering research in triboelectrification-induced electroluminescence has advanced the development of self-powered photonic and sensing materials, enabling innovative applications in intelligent wearables, visualized sensing, and interactive technologies. Her work bridges materials science and sustainable energy, driving global innovation toward smarter, energy-efficient devices that enhance human–machine interaction and environmental monitoring.

Lai Feng | Materials Science and Engineering | Best Researcher Award

Prof. Lai Feng | Materials Science and Engineering | Best Researcher Award

Soochow University | China

Prof. Lai Feng is a distinguished Professor at the Soochow Institute for Energy and Materials Innovations (SIEMIS), College of Energy, Soochow University, China. He obtained his Ph.D. in Inorganic Chemistry from Peking University (2003) and both M.S. and B.S. degrees in Fine Chemical Engineering from Dalian University of Technology. His professional journey includes esteemed international research appointments, notably as a Senior Researcher at the University of Tsukuba, Japan (2008–2012), a Humboldt Fellow at Friedrich-Alexander-Universität Erlangen-Nürnberg, Germany (2006–2007), and a JSPS Fellow at Tsukuba University (2003–2005). Prof. Feng’s research spans across electrocatalytic synthesis of clean fuels such as hydrogen and ammonia, development of all-inorganic perovskite solar cells, and the design of fullerene-based carbon materials. His pioneering work has significantly advanced the understanding of catalytic mechanisms and energy conversion processes at the nanoscale, contributing to sustainable energy technologies. He has authored numerous high-impact publications in journals such as Nature Communications, Advanced Functional Materials, and Accounts of Chemical Research, with his research garnering substantial citations and global recognition. His recent studies on multifunctional nanostructured catalysts have opened new pathways for efficient hydrogen evolution and carbon-neutral energy applications. Prof. Feng actively collaborates with international research teams from Europe, Japan, and China, fostering cross-disciplinary innovation in materials chemistry and renewable energy. His contributions have had notable societal impact by promoting green chemical synthesis and sustainable energy systems, aligning with global efforts toward carbon neutrality. With his continuous commitment to excellence in scientific inquiry and international collaboration, Prof. Lai Feng stands as a leading figure in the field of energy materials and catalysis research, advancing both academic knowledge and technological progress for a sustainable future.

Profile: ORCID
Featured Publications:

Elijah Kusi | Green Building Design | Best Researcher Award

Dr. Elijah Kusi | Green Building Design | Best Researcher Award

lecturer | The Akenten Appiah-Menka University of Skills Training and Entrepreneurial Development | Ghana

Dr. Elijah Kusi is an emerging academic and researcher specializing in Construction Technology, Architectural Engineering, and Sustainable Building Design, with strong expertise in energy efficiency, thermal comfort, and natural ventilation in buildings. He currently serves as a Lecturer at the Akenten Appiah-Menka University of Skills Training and Entrepreneurial Development (AAMUSTED), Ghana, where he teaches a broad range of courses including Building Science, Computer-Aided Design (CAD), Building Materials, and Sustainable Construction. His academic qualifications include a B.Sc. in Architecture from the Kwame Nkrumah University of Science and Technology, an M.Phil. in Construction Technology from the University of Education, Winneba, and a Ph.D. in Construction Technology (ongoing) at AAMUSTED. His ongoing doctoral research investigates indoor thermal comfort in naturally ventilated university classrooms, contributing valuable insights into climate-responsive and energy-efficient educational infrastructure. Dr. Kusi has authored and co-authored multiple peer-reviewed publications in reputable international journals, including the International Journal of Building Pathology and Adaptation, Cogent Engineering, and the Journal of Construction Project Management and Innovation. His scholarly works explore diverse themes such as green building technologies, energy consumption modeling, project management, and e-procurement in construction. He has actively presented research at international conferences, earning Best Poster Presentation Awards at the CIB W123 and W099 Conference (2024) and the AAMUSTED Postgraduate Research Conference (2024). A member of professional and academic bodies such as the Institution of Engineering and Technology (Ghana), Ghana Science Association, and the Society of Building Science Educators (USA), Dr. Kusi’s collaborative and interdisciplinary research aims to advance sustainable construction practices in Ghana and globally. His work has significantly contributed to the promotion of green architecture, resource efficiency, and knowledge management within the construction industry, fostering innovation aligned with global sustainability goals.

Profile: Scopus | ORCID
Featured Publications
  • Energy consumption and carbon emission of conventional and green buildings using building information modelling (BIM). (2025). International Journal of Building Pathology and Adaptation. 16 Citations.

Yunus Gündüz | Biocomposite Materials | Best Researcher Award

Yunus Gündüz | Biocomposite Materials | Best Researcher Award

Research Assistant | Yozgat Bozok University | Turkey

Yunus Gündüz is an emerging researcher whose academic contributions reflect a focused engagement in contemporary scientific domains, emphasizing innovation, applied research, and interdisciplinary collaboration. His research activity demonstrates a growing influence within his specialized field, contributing to the advancement of both theoretical understanding and practical applications. The publication record attributed to him includes several peer-reviewed journal articles and conference papers that collectively showcase his analytical capability and commitment to addressing real-world challenges through rigorous methodologies. His work has been cited 37 times in total, with 35 citations received since 2020, indicating a consistent and upward trend in scholarly recognition. According to citation metrics, Yunus Gündüz holds an h-index of 4 (3 since 2020) and an i10-index of 1 (1 since 2020), highlighting the academic impact and visibility of his contributions in the research community. His collaborations with diverse academic and professional partners have enriched the cross-disciplinary relevance of his studies, leading to outcomes with notable societal and technological implications. Through his sustained research efforts, Yunus Gündüz continues to strengthen the connection between scientific inquiry and societal benefit, contributing to the global pursuit of knowledge and innovation.

Profile: Google Scholar
Featured Publications:
  • Gündüz, Y., Taşkan, E., & Şahin, Y. (2016). Using hooked-end fibres on high performance steel fibre reinforced concrete. High Perform. Optim. Des. Struct. Mater. II, 1, 265–276.

  • Şahin, Y., & Gündüz, Y. (2024). PCMs with perlite aggregate for snow melting applications. Sustainable Energy Technologies and Assessments, 62, 103617.

  • Gündüz, Y. (2015). Çelik tel donatılı betonlarda kırılma parametrelerinin yapay sinir ağları ile modellenmesi. Yüksek lisans tezi, Yozgat Bozok Üniversitesi.

  • Gündüz, Y., & Şahin, Y. (2021). Relation of the thermal conductivity and the electrical resistivity to the unit weight of hemp based composites. International Journal of Thermophysics, 42(7), 103.

  • Ozel, B. F., Sakallı, Ş., Gündüz, Y., & Şahin, Y. (2025). Freeze–thaw resistance of pervious concrete produced with different aggregates and fibres. Road Materials and Pavement Design, 26(8), 1951–1973.

Rehab F. Abdel-Kader | Smart Transportation Systems | Women Researcher Award

Prof. Rehab F. Abdel-Kader | Smart Transportation Systems | Women Researcher Award

Chair of Graduate Studies and Research | ElSewedy university of technology | Egypt

Prof. Rehab F. Abdel-Kader is a distinguished Professor of Computer Engineering and Chair of Graduate Studies and Research at ElSewedy University of Technology, Cairo, Egypt. Her academic journey spans Auburn University, Tuskegee University, and Suez-Canal University, culminating in a Ph.D. in Computer Science and Engineering (2003). With more than two decades of research and teaching experience, her expertise encompasses artificial intelligence, image processing, computer vision, big data analytics, and intelligent optimization algorithms. Prof. Abdel-Kader has authored and co-authored over 70 peer-reviewed publications in high-impact international journals and conferences, contributing significantly to areas such as deep learning-based image analysis, optimization for IoT and cloud-fog systems, and AI-driven smart infrastructure. Her scholarly impact is reflected in Cited by: All 1077, Since 2020 524, h-index 18 (12 since 2020), and i10-index 22 (15 since 2020). She has served as Principal Investigator for major funded projects, including the Science and Technology Development Fund (STDF) grant for “AI End-to-End Multi-Sensor Pavement Distress Detection” and collaborative initiatives with Microsoft and Nile University on intelligent systems for real-time environmental and urban management. Her academic influence extends globally through editorial roles in engineering journals, Springer book editorships, and conference leadership such as the International Conference on Advanced Machine Learning and Technologies and Applications (AMLTA) and Engineering Solutions Toward Sustainable Development (ESSD). Prof. Abdel-Kader’s mentorship of numerous Ph.D. and M.Sc. students has advanced applied AI research in Egypt and beyond. Her work bridges academia, industry, and policy, fostering sustainable technological innovation and contributing to the digital transformation of engineering education and infrastructure systems.

Profile: Scopus | Google Scholar | ORCID
Featured Publications:
  • Ramadan, R. M., & Abdel-Kader, R. F. (2009). Face recognition using particle swarm optimization-based selected features. International Journal of Signal Processing, Image Processing and Pattern Recognition.

  • Abdel-Kader, R. F. (2010). Genetically improved PSO algorithm for efficient data clustering. 2010 Second International Conference on Machine Learning and Computing, 71–75.

  • Abdel-Kader, R. F. (2011). Hybrid discrete PSO with GA operators for efficient QoS-multicast routing. Ain Shams Engineering Journal, 2(1), 21–31.

  • Magdy, A., Hussein, H., Abdel-Kader, R. F., & Abd El Salam, K. (2023). Performance enhancement of skin cancer classification using computer vision. IEEE Access, 11, 72120–72133.

  • Moussa, A. M., & Abdel-Kader, R. F. (2011). Qasyo: A question answering system for YAGO ontology. International Journal of Database Theory and Application, 4(2), 99–112.

  • Hedeya, M. A., Eid, A. H., & Abdel-Kader, R. F. (2020). A super-learner ensemble of deep networks for vehicle-type classification. IEEE Access, 8, 98266–98280.

Rehab Abdel-Kader’s research advances artificial intelligence and computational intelligence through innovative applications of particle swarm optimization, machine learning, and deep learning. Her work has significantly contributed to enhancing pattern recognition, medical image analysis, and intelligent data processing, driving scientific progress and fostering technological innovation across healthcare, transportation, and information systems worldwide.

Mahasakti Mahamaya | Geotechnical Engineering | Women Researcher Award

Dr. Mahasakti Mahamaya | Geotechnical Engineering | Women Researcher Award

Associate Professor | OP Jindal University | India

Dr. Mahasakti Mahamaya is a distinguished researcher whose academic contributions span across engineering and interdisciplinary sciences, with a focus on innovative methodologies, sustainable development, and applied technologies. Her research portfolio demonstrates significant depth, addressing complex real-world challenges through analytical precision and forward-looking inquiry. Dr. Mahamaya has authored a substantial number of peer-reviewed papers in reputed international journals and conferences, contributing extensively to the advancement of knowledge in her field. Her work has attracted a remarkable level of global attention, reflected through 483 total citations and 445 citations since 2020, underscoring the continuing influence of her research. With an h-index of 10 and an i10-index of 10, Dr. Mahamaya has consistently maintained scholarly excellence and research impact across multiple domains. She has actively collaborated with experts and institutions worldwide, strengthening multidisciplinary networks and fostering the integration of academic research with industry and policy frameworks. Her studies have advanced understanding in areas such as material behavior, computational modeling, and sustainable engineering practices, while also highlighting the societal and environmental implications of technological innovation. Through mentorship, publication, and collaborative initiatives, Dr. Mahamaya has contributed to nurturing a new generation of researchers and to shaping future-oriented strategies in engineering and applied science. Her sustained academic engagement and global recognition underscore a career dedicated to impactful, ethically grounded, and socially relevant scientific inquiry, positioning her as a leading figure in her research domain.

Featured Publications:

Suman, S., Mahamaya, M., & Das, S. K. (2016). Prediction of maximum dry density and unconfined compressive strength of cement stabilised soil using artificial intelligence techniques. International Journal of Geosynthetics and Ground Engineering, 2(2), 1–11.

Mahamaya, M., Das, S. K., Reddy, K. R., & Jain, S. (2021). Interaction of biopolymer with dispersive geomaterial and its characterization: An eco-friendly approach for erosion control. Journal of Cleaner Production, 127778.

Parhi, P. S., Garanayak, L., Mahamaya, M., & Das, S. K. (2017). Stabilization of an expansive soil using alkali activated fly ash based geopolymer. International Congress and Exhibition "Sustainable Civil Infrastructures".

Mahamaya, M., & Das, S. K. (2017). Characterization of mine overburden and fly ash as a stabilized pavement material. Particulate Science and Technology, 35(6), 660–666.

Das, S. K., Mahamaya, M., & Reddy, K. R. (2020). Coal mine overburden soft shale as a controlled low strength material. International Journal of Mining, Reclamation and Environment, 34(10), 725–747.

Changxin Huang | Geotechnical Engineering | Best Researcher Award

Dr. Changxin Huang | Geotechnical Engineering | Best Researcher Award

Doctoral student | Shandong University | China

The research fields of Dr. Changxin Huang encompass advanced studies in sustainable and intelligent civil engineering materials, focusing primarily on multifunctional and smart concretes through the integration of nanotechnology. The research explores the development of high-performance cementitious composites with self-sensing, self-healing, and durability-enhancing capabilities to address challenges in modern infrastructure systems. Emphasis is placed on the design and optimization of nano-engineered materials such as carbon-based nanomaterials, graphene, and carbon nanotubes to improve mechanical strength, electrical conductivity, and structural monitoring efficiency. Huang’s work also extends to the application of intelligent monitoring systems for civil infrastructure, utilizing embedded sensors and data-driven technologies to enable real-time structural health monitoring and predictive maintenance. Additional areas of interest include green and sustainable construction materials, energy-efficient concrete structures, and recycling of industrial by-products for eco-friendly material synthesis. The research integrates experimental testing, numerical modeling, and machine learning approaches to predict material performance and optimize formulation strategies. Huang’s contributions aim to bridge material science and structural engineering, promoting the transition toward intelligent, resilient, and low-carbon construction systems. The interdisciplinary approach combines principles from materials engineering, nanotechnology, and data analytics to enhance infrastructure performance and sustainability. Overall, the research advances the vision of next-generation civil infrastructure that is adaptive, energy-efficient, and environmentally responsible through innovative multifunctional concrete technologies and smart monitoring systems.

Profile: Scopus | ORCID
Featured Publications:

A stepwise calculation method for grouting penetration in rough rock fracture based on fracture segment division. (2025). Tunnelling and Underground Space Technology.

Mr. Harish Kumar Srivastava | Decarbonization of Concrete | Best Researcher Award

Mr. Harish Kumar Srivastava | Decarbonization of Concrete | Best Researcher Award

Research Scholar | Maquarie University | Australia

Mr. Harish Kumar Srivastava is a distinguished professional in civil and structural engineering with over three decades of experience in leading multidisciplinary infrastructure projects across Australia, New Zealand, India, Africa, Southeast Asia, and the Pacific. His expertise lies in decarbonisation of concrete, maritime infrastructure, transport facilities, and sustainable engineering solutions. As Director Technical Maritime at Transport for NSW, he provides strategic leadership in innovation, sustainability integration, and technical risk mitigation for projects involving maritime assets, zero-emission bus depots, and transport facilities. His research focuses on low-carbon concrete development, incorporating recycled materials, ultra-high-performance concrete, and supplementary cementitious materials to reduce embodied carbon. Harish is actively engaged with SmartCrete CRC and MECLA, contributing to a nationwide effort on material decarbonisation. He has co-authored numerous publications addressing carbon reduction strategies, optimization of concrete mix design, and applications of AI and live digital twins for infrastructure asset management. His work extends to standard development with RISSB, PIANC, and TfNSW, promoting harmonized specifications and sustainable practices across the transport sector. Harish’s contributions reflect a deep commitment to advancing engineering innovation, resource efficiency, and climate-responsive infrastructure development.

Profile: ORCID 
Fearuted Publications:

Srivastava, H. K., Vimonsatit, V., & Clark, S. M. (2025). A systematic approach for selection of fit-for-purpose low-carbon concrete for various bridge elements to reduce the net embodied carbon of a bridge project. Infrastructures.

Srivastava, H. K. (2024). AS 7630 - Track classification. RISSB Standards Australia.

Srivastava, H. K. (2024). Decarbonisation of concrete – A systematic bottom-up approach. In Proceedings of BEI 2024.

Srivastava, H. K. (2024). Effects of supplementary cementitious materials on strength and design of precast concrete bridge elements and associated structures. In Proceedings of BEI 2024.

Srivastava, H. K. (2023). The decarbonisation of concrete – Alternative strategies. In Proceedings of AusRail Plus 2023.

Srivastava, H. K. (2023). Multi-objective optimization of calcination process fuel input for lowering carbon footprint. In Proceedings of Concrete 2023.