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)

Kristína Compelová | Materials Science and Engineering | Best Researcher Award

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Kristína Compelová | Materials Science and Engineering | Best Researcher Award

Doctorand | Slovak University of Technology in Bratislava | Slovakia

Kristína Compelová is a dedicated early-career researcher specializing in inorganic technologies and materials within the Faculty of Chemical and Food Technology at the Slovak University of Technology in Bratislava, where she is currently pursuing her PhD. With a strong background in chemical technologies and engineering, her academic progression from bachelor’s to doctoral studies reflects her deep commitment to advancing materials science research. She holds concurrent research assistant positions at both the Slovak University of Technology and the Institute of Construction and Architecture of the Slovak Academy of Sciences, demonstrating her active involvement in interdisciplinary research. Her work focuses on experimental investigations and material characterization through advanced analytical techniques such as thermogravimetric analysis (TGA), X-ray diffraction (XRD), Fourier-transform infrared spectroscopy (FTIR), and scanning electron microscopy (SEM). She possesses expertise in data processing and interpretation using scientific software tools like Origin, and her research contributions aim to improve understanding of material behavior and structural performance in construction and industrial applications. Throughout her academic and research career, Compelová has contributed to collaborative projects bridging chemical and construction materials research, emphasizing innovation, environmental responsibility, and scientific rigor. Her analytical proficiency and methodical approach enable her to deliver precise experimental results and comprehensive data analyses that contribute to the broader objectives of sustainable material development. She has participated in several institutional research efforts that foster interdisciplinary collaboration and promote scientific advancement in Slovakia’s academic community. With a strong command of English and fundamental German proficiency, she actively engages with international literature and scientific discourse. Her evolving research profile positions her as a promising scientist with potential to make meaningful contributions to the fields of material science, environmental chemistry, and sustainable technologies, reinforcing her commitment to the advancement of applied chemical research and its societal impact.

Profile: Scopus
Publications:

Chloride and combined chemical attack of saline solutions on modified oil well cement pastes. Journal of Thermal Analysis and Calorimetry.

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.

Yunus Gündüz | Biocomposite Materials | Best Researcher Award

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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.

Ghizlane Moutaoukil | Sustainable construction materials | Eco-friendly Construction Practices Award

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Dr. Ghizlane Moutaoukil | Sustainable construction materials | Eco-friendly Construction Practices Award

Postdoctoral researcher | Centro de Física de Materiales (CFM) | Spain

Dr. Ghizlane Moutaoukil is a distinguished researcher in materials chemistry and environmental science, specializing in the synthesis, characterization, and thermomechanical evaluation of sustainable construction materials. With a PhD jointly earned from Mohammed V University in Rabat and the Institute of Materials Science of Madrid, the research focuses on the development of dense and porous geopolymers derived from industrial waste. Extensive investigations cover the optimization of mechanical and microstructural properties of fly ash-based geopolymers, thermomechanical behavior, foaming processes, and the integration of radiative cooling functions in cementitious composites. As a postdoctoral researcher at the Centro de Fisica de Materiales (CSIC/UPV-EHU), Moutaoukil continues advancing sustainable materials for environmental and energy applications. The impressive publication record in journals such as Materials Letters, Advanced Science, and Construction and Building Materials reflects deep expertise in MAS NMR, FTIR, XRD, and Raman spectroscopy. Patents and collaborative works, notably the “Modern Roman-Inspired Concrete with Daytime Radiative Cooling Capacity,” demonstrate innovative thinking bridging chemistry and civil engineering. Research also includes the mechanosynthesis of phosphate mine waste-based geopolymers and geochemical applications for pollution control. Proficiency in Arabic, French, English, and Spanish strengthens global collaboration capacity. Technical mastery extends to process engineering, corrosion studies, and rheological analysis, with strong computational and statistical design skills. Active participation in international conferences from Morocco to Spain and Turkey underscores commitment to interdisciplinary scientific exchange. Ghizlane Moutaoukil’s contributions—166 citations, 12 publications, and an h-index of 6—reflect consistent research excellence and growing global recognition, making Ghizlane Moutaoukil a promising leader in sustainable materials and environmental innovation.

Profile: Scopus | ORCID
Featured Publications:

Ghizlane Moutaoukil, Isabel Sobrados, & Jorge S. Dolado. (2025, October). Development of phosphate mine waste-based geopolymer by mechanosynthesis. Construction and Building Materials, 143573.

Jorge S. Dolado, Guido Goracci, Ghizlane Moutaoukil, Ridwan O. Agbaoye, Miguel Beruete, Alicia E. Torres‐García, Laura Carlosena, Achutha Prabhu, Jose A. Ibáñez, Nick Adams, et al. (2025, September 12). A modern Roman-inspired concrete with daytime radiative cooling capacity. Advanced Science.

Ghizlane Moutaoukil, Isabel Sobrados, H. Süleyman Gökçe, & Saliha Alehyen. (2025, June). Effect of thermal treatment, foaming and stabilizing agents on the synthesis of fly ash-based geopolymer foams using Raman spectroscopy and 29Si and 27Al MAS NMR. Sustainable Chemistry for the Environment, 100257.

Ghizlane Moutaoukil, Isabel Sobrados, Saliha Alehyen, & M’hamed Taibi. (2024, May 16). Monitoring the geopolymerization reaction of geopolymer foams using 29Si and 27Al MAS NMR. Minerals, 14(5), 516.

Ghizlane Moutaoukil, Isabel Sobrados, Saliha Alehyen, & M’hamed Taibi. (2024, March). Understanding the thermomechanical behavior of geopolymer foams: Influence of rate and type of foaming agent and stabilizer. Chemical Data Collections, 101111.

Ghizlane Moutaoukil, Saliha Alehyen, Isabel Sobrados, & Amine El Mahdi Safhi. (2023, June). Effects of elevated temperature and activation solution content on microstructural and mechanical properties of fly ash-based geopolymer. KSCE Journal of Civil Engineering.

Kundan Yadav – Construction Materials – Innovative Solutions for Environmental Challenges Award

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Mr. Kundan Yadav | Construction Materials | Innovative Solutions for Environmental Challenges Award

Research Scholar | Lovely Professional University | Nepal

Mr. Kundan Yadav has established a strong research and professional profile in the field of civil engineering and construction management with a focus on sustainable practices, low-carbon materials, and resilient infrastructure solutions. His work integrates both academic research and practical implementation, spanning hydropower, bridges, urban water supply, sanitation systems, and building construction. A key area of his research revolves around eco-friendly materials, particularly the use of supplementary cementitious materials, plastic bricks, and biochar as innovative alternatives to reduce carbon emissions and promote circular construction. Publications in peer-reviewed journals highlight his exploration of carbon quantification methods and best practices for emission reduction, reflecting a commitment to advancing sustainability in construction. Professionally, Kundan Yadav has taken progressive roles from Site Engineer to Project Manager, contributing to projects funded by organizations like the World Bank and Asian Development Bank, ensuring quality control, safety compliance, and project efficiency. His leadership in managing hydropower retrofitting, bridge construction, trauma center building, and large-scale infrastructure projects demonstrates expertise in structural stability, resilience, and sustainable project delivery. By combining technical knowledge in AutoCAD, Staad Pro, MS Project, MATLAB, and sustainability assessment with practical construction management skills, he bridges the gap between theory and practice. His work emphasizes transforming waste into valuable construction resources, reducing environmental impact, and promoting innovation in materials science. The consistent focus on resilience and carbon reduction showcases his vision of sustainable infrastructure development tailored to the needs of South Asia, where rapid urbanization demands eco-conscious solutions. Through both research and professional practice, Kundan Yadav contributes to advancing civil engineering toward a future that prioritizes environmental sustainability, efficient resource utilization, and long-term durability of infrastructure systems, marking him as a significant contributor to sustainable construction research and practice.

Profile: Google Scholar
Featured Publications:

  1. Sustainable development by carbon emission reduction and its quantification: An overview of current methods and best practices. (2023). Cited by 21.

  2. Transforming waste into innovation: A review of plastic bricks as sustainable construction materials. (2024). Cited by 13.

  3. Sustainable solutions: Exploring supplementary cementitious materials in construction. (2025). Cited by 7.

  4. Comparative study of biochar and charcoal and their application in the construction industry. (2024). Cited by 5.

  5. Waste water characteristics and its management in and around HSTU campus of Bangladesh. (2021).

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).

Dr. C. Vigneshkumar | Construction Management | Best Researcher Award

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Dr. C. Vigneshkumar | Construction Management | Best Researcher Award

Postdoctoral Fellow | The Hong Kong Polytechnic University | India 

Dr. Vigneshkumar Chellappa has established a strong research foundation in the domains of human factors, ergonomics, construction safety, and design innovation, with a particular emphasis on prevention through design and occupational health in construction industries. His work focuses on integrating ergonomic principles with construction safety management, aiming to minimize risks and enhance well-being through effective strategies. Vigneshkumar has contributed significantly to developing frameworks and applications of game-based learning, immersive virtual reality, and digital technologies to strengthen hazard recognition skills, improve knowledge management practices, and create innovative training methods for construction workers. His research also investigates barriers to safety implementation, risk assessment processes, and user-centered design approaches, addressing both technological and human-centered challenges in construction. Collaborations with international institutions have broadened his work on safety culture, sustainability in education, and inclusive design practices. He has advanced the discourse on safety helmet redesign, corporate social responsibility in construction, and ergonomic risk assessment using digital human modeling and digital twin technologies. Vigneshkumar’s contributions extend to cross-disciplinary applications of ergonomics, psychological well-being, and design education, with notable publications in leading journals and conferences. His research outcomes emphasize practical strategies for safety improvement while bridging gaps between theory and practice in civil engineering and design. His dedication to occupational safety, risk management, and innovative design-based methodologies continues to gain recognition through awards, fellowships, and scholarly impact across global academic and professional communities. With 42 publications, 229 citations from 139 documents, and an h-index of 7.

Profile: Google Scholar | Scopus | ORCID
Publications:

  1. Safety knowledge management practices in Indian construction companies. (2022). Cited by 9.

  2. Digital twin approach for the ergonomic evaluation of vertical formwork operations in construction. (2023). Cited by 8.

  3. Digital technologies (DTs) for safety education and training in construction. (2024). Cited by 7.

  4. Analysis of workers’ fall accidents due to formwork operations. (2022). Cited by 7.

  5. Application of multiple-criteria decision making methods for construction safety research. (2024). Cited by 6.

Marie Giroudon – Civil and environmental engineering – Best Researcher Award

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Marie Giroudon - Civil and environmental engineering - Best Researcher Award

INSA Toulouse - France

AUTHOR PROFILE

GOOGLE SCHOLAR 

SCOPUS

🔬 SUMMARY

Marie Giroudon is a pioneering researcher in civil engineering, specializing in the sustainability and durability of cementitious materials under aggressive conditions. Grounded in both academic excellence and hands-on experimentation, the work contributes meaningfully to environmental engineering and sustainable construction. With a strong interdisciplinary approach, Marie bridges civil engineering with microbiological and biochemical phenomena, particularly in the context of biogas and anaerobic digestion infrastructures. The research explores how binders, additives, and natural aggregates behave in corrosive environments, aiming to develop low-carbon, bio-integrated materials that withstand biodeterioration. The innovative contributions have gained recognition across both scientific and industrial communities, notably in Europe. Presently working as Maître de Conférences at INSA Toulouse, the career reflects a continuous trajectory of academic distinction, impactful collaborations, and scientific leadership. With a solid publication record and active roles in international working groups, Marie continues to shape the future of sustainable and durable construction materials research globally.

📘 EARLY ACADEMIC PURSUITS

Marie Giroudon’s academic path reflects a steady ascent through top-tier institutions and rigorous programs in science and engineering. The journey began with a Bachelor's degree in Physics at Université Toulouse III Paul Sabatier, attained with distinction. The foundation in physics cultivated a strong analytical and technical perspective, later channeled into civil and geotechnical engineering. The academic development continued through a Master’s and Engineering diploma from UPSSITECH, marked by honors and international exposure through a semester at Polytechnique Montréal. The formal academic training culminated in a PhD in Civil Engineering from INSA Toulouse, successfully defended in January 2021. The thesis explored interactions between biowaste in anaerobic digestion and cement-based materials, laying the groundwork for future innovations in eco-resilient infrastructure. Throughout this formative period, Marie consistently demonstrated high aptitude, curiosity, and commitment to research excellence, supported by prestigious grants and supervision under renowned French experts in materials durability and sustainable construction.

🏗️ PROFESSIONAL ENDEAVORS

Marie Giroudon's professional experience showcases a seamless blend of research, teaching, and interdisciplinary project leadership. Currently serving as Maître de Conférences at INSA Toulouse within the Laboratoire Matériaux et Durabilité des Constructions (LMDC), the role integrates research on cementitious materials with pedagogy across subjects such as BIM, geotechnics, and prestressed concrete. Previously, Marie contributed to cutting-edge postdoctoral projects like WWT Concrete, targeting sustainable solutions for wastewater infrastructure. These roles followed a rich doctoral journey supported by ANR BIBENdOM, focusing on how cement-based materials react in biodeteriorative, anaerobic conditions. Each professional role has been guided by a strong commitment to innovation and sustainability. With active involvement in mentoring research students and coordinating academic collaborations across institutions like EPFL and Université Gustave Eiffel, the career reflects a mature scientific vision combined with practical leadership in environmental and construction material research. These roles reinforce Marie's expertise in applying fundamental science to real-world engineering challenges.

🧪 CONTRIBUTIONS AND RESEARCH FOCUS

The research of Marie Giroudon addresses critical challenges in environmental engineering by focusing on the durability of cementitious materials in chemically aggressive settings, particularly anaerobic digestion systems. By investigating alternative binders such as metakaolin geopolymers, blast-furnace slag cement, and calcium aluminate cement, the work contributes to lowering the environmental footprint of construction. Key innovations include identifying the biodeterioration kinetics and interaction mechanisms between organic matter and cement matrices. Marie's investigations into materials behavior under exposure to ammonium, organic acids, and fermentation byproducts are crucial for designing long-lasting bio-infrastructure. Collaborations with biotechnologists and environmental chemists have enriched these studies with multidisciplinary insights. Through over 15 peer-reviewed articles and numerous conference presentations, Marie has established a strong scientific presence in sustainable materials research. The work influences guidelines for agricultural and industrial infrastructure, particularly biogas plants, and contributes to European discussions on green civil engineering, forming the scientific basis for future innovations in eco-construction.

🏅 ACCOLADES AND RECOGNITION

Marie Giroudon has earned several recognitions that underscore both scientific excellence and community engagement. A prominent achievement includes winning the 3rd prize at the “Forum Jeunes Chercheurs” in Marne la Vallée for research on biodeterioration of cement materials—an acknowledgment of originality and societal relevance. As a dedicated member of international expert committees like RILEM TC 253-MCI and the French Civil Engineering Association’s “Bétons et Microorganismes” group, Marie contributes actively to shaping technical documentation and standards on microbial impacts on concrete. Participation in these expert networks reflects not only scientific credibility but also an enduring commitment to collaborative advancement. Furthermore, the invitation to contribute to state-of-the-art reports published by Springer, and repeated representation at top-tier conferences such as the International Congress on the Chemistry of Cement, highlight widespread recognition. These honors affirm Marie’s status as a rising leader in the domain of eco-resilient construction materials and sustainable civil infrastructure research.

🌍 IMPACT AND INFLUENCE

Marie Giroudon's research exerts tangible influence on both academic and applied sectors, particularly in the design and maintenance of biogas infrastructure and wastewater facilities. The interdisciplinary work directly informs environmental policy and engineering practices by providing evidence-based insights into material degradation in microbial and chemical environments. Collaborations with major public utilities like SIAAP and universities such as EPFL have fostered research-to-practice translation. The development of low-carbon, bio-integrated binders presents a promising direction in the global shift toward sustainable construction, aligning with EU climate goals. The work contributes significantly to reducing lifecycle emissions from concrete structures by substituting conventional Portland cement with geopolymer and aluminate alternatives. Moreover, Marie’s mentorship of graduate students ensures that this impact extends through a new generation of eco-conscious engineers. Through scholarly publications, cross-disciplinary research projects, and leadership in technical networks, the contributions continue to shape research trajectories, industrial protocols, and sustainability standards across Europe and beyond.

🧱 LEGACY AND FUTURE CONTRIBUTIONS

Marie Giroudon’s legacy lies in pioneering eco-durability within civil engineering and creating a research foundation that combines chemical resilience, microbial science, and materials engineering. The emerging expertise in micromechanical analysis and nanoindentation of cementitious composites paves the way for future breakthroughs in infrastructure diagnostics. Current recruitment for PhD and postdoctoral positions under Marie’s guidance signals a growing research lab ecosystem focused on innovative materials in leaching and bio-reactive environments. With active roles in scientific communities, the next decade is poised to see deeper exploration into LC3-type low-carbon materials, resistance modeling under multiaxial stress conditions, and long-term simulations of degradation pathways. Furthermore, the integration of sustainability into structural engineering curricula ensures lasting academic influence. With a track record of practical, publication-driven, and collaborative research, Marie’s future contributions will likely redefine durability standards for green buildings and bio-infrastructure, thereby reinforcing global efforts toward resilient, sustainable urban and rural development through advanced material science.

NOTABLE PUBLICATIONS

Title: Comparison of barley and lavender straws as bioaggregates in earth bricks
Authors: M. Giroudon, A. Laborel-Préneron, J.E. Aubert, C. Magniont
Journal: Construction and Building Materials, Vol. 202, pp. 254–265 (2019)

Title: Blast-furnace slag cement and metakaolin based geopolymer as construction materials for liquid anaerobic digestion structures: Interactions and biodeterioration mechanisms
Authors: M. Giroudon, M.P. Lavigne, C. Patapy, A. Bertron
Journal: Science of The Total Environment, Vol. 750, Article 141518 (2021)

Title: Cementitious materials in biogas systems: Biodeterioration mechanisms and kinetics in CEM I and CAC based materials
Authors: C. Voegel, M. Giroudon, A. Bertron, C. Patapy, P.L. Matthieu, T. Verdier, ...
Journal: Cement and Concrete Research, Vol. 124, Article 105815 (2019)

Title: Experimental assessment of bio-based earth bricks durability
Authors: A. Laborel-Préneron, M. Giroudon, J.E. Aubert, C. Magniont, P. Faria
Journal: IOP Conference Series: Materials Science and Engineering, Vol. 660 (1), Article 012069 (2019)

Title: Potential of low carbon materials facing biodeterioration in concrete biogas structures
Authors: M. Giroudon, C. Patapy, M. Peyre Lavigne, M. Andriamiandroso, R. Cartier, ...
Journal: Materials and Structures, Vol. 56 (4), Article 80 (2023)

Title: Insights into the local interaction mechanisms between fermenting broken maize and various binder materials for anaerobic digester structures
Authors: M. Giroudon, C. Perez, M.P. Lavigne, B. Erable, C. Lors, C. Patapy, A. Bertron
Journal: Journal of Environmental Management, Vol. 300, Article 113735 (2021)