Elżbieta Radziszewska-Zielina | Engineering | Best Researcher Award

Published on by Forensic Scientist

Prof. Dr. Elżbieta Radziszewska-Zielina | Engineering | Best Researcher Award

Cracow University of Technology | Poland

Prof. Dr. Elżbieta Radziszewska-Zielina is a distinguished researcher from Politechnika Krakowska, Krakow, Poland, widely recognized for her pioneering work in civil engineering, sustainable construction management, and intelligent systems for project engineering. Her research bridges technical innovation, computational modeling, and sustainability principles to enhance efficiency, environmental responsibility, and resilience in the built environment. She has published 59 scientific papers indexed in Scopus, which have collectively received 838 citations, yielding a Scopus h-index of 20, reflecting her strong academic influence and international recognition. Her studies focus on modern construction materials, energy-efficient building technologies, blue-green infrastructure, and systemic approaches to reducing greenhouse gas emissions in urban construction. Her innovative use of computational techniques—including type-1 and type-2 fuzzy logic, stochastic networks, multi-criteria decision analysis, and optimization algorithms—has advanced the understanding and practical application of complex construction processes. Prof. Dr. Elżbieta Radziszewska-Zielina’s notable research outputs include the development of decision-support systems for construction planning, models for adaptive reuse of historic buildings, and optimization frameworks for nearly zero-energy buildings. She has contributed to key international research and educational projects funded by the National Science Centre (NCN), National Centre for Research and Development (NCBR), Horizon 2020, and other European programs. Her editorial leadership includes guest editing special issues in Sustainability, Polymers, and Open Engineering, and serving on the boards of Archives of Civil Engineering and Selected Scientific Papers – Journal of Civil Engineering.

Profiles: Scopus | Google Scholar | ORCID | ResearchGate

Featured Publications

  • Kania, E., Radziszewska-Zielina, E., & Śladowski, G. (2020). Communication and information flow in Polish construction projects. Sustainability, 12(21), 9182. https://doi.org/10.3390/su12219182

  • Radziszewska-Zielina, E., & Śladowski, G. (2017). Supporting the selection of a variant of the adaptation of a historical building with the use of fuzzy modelling and structural analysis. Journal of Cultural Heritage, 26, 53–63. https://doi.org/10.1016/j.culher.2017.02.007

  • Radziszewska-Zielina, E., Śladowski, G., & Sibielak, M. (2017). Planning the reconstruction of a historical building by using a fuzzy stochastic network. Automation in Construction, 84, 242–257. https://doi.org/10.1016/j.autcon.2017.09.005

  • Radziszewska‐Zielina, E. (2010). Methods for selecting the best partner construction enterprise in terms of partnering relations. Journal of Civil Engineering and Management, 16(4), 510–520. https://doi.org/10.3846/jcem.2010.57

  • Korytárová, J., Hanák, T., Kozik, R., & Radziszewska–Zielina, E. (2015). Exploring the contractors’ qualification process in public works contracts. Procedia Engineering, 123, 276–283. https://doi.org/10.1016/j.proeng.2015.10.084

Volodymyr Hovorukha | Engineering | Best Researcher Award

Published on by Forensic Scientist

Mr. Volodymyr Hovorukha | Engineering | Best Researcher Award

M.S. Poliakov Institute of Geotechnical Mechanics of the National Academy of Sciences of Ukraine | Ukraine

Mr. Volodymyr Hovorukha is a prominent Ukrainian scientist whose pioneering contributions have shaped the fields of railway engineering, transport mechanics, and structural dynamics. As a Senior Researcher at the M.S. Poliakov Institute of Geotechnical Mechanics of the National Academy of Sciences of Ukraine, he has made outstanding advancements in understanding the interaction between rail tracks and moving transport systems, the mechanics of deformation, and the reliability of rail infrastructure. His scientific achievements encompass the development of over ten mathematical models addressing dynamic rail–vehicle interaction, wear processes, and derailment safety, particularly under the influence of friction modifiers. He has authored more than 240 scientific papers, including publications indexed in international databases such as Scopus, and four monographs registered with ISBN. Mr. Volodymyr Hovorukha holds 32 patents, three of which have been officially recognized as international discoveries in railway transport. His innovative research has led to the creation of modernized track structures, high-speed rail fastening systems, and reinforced concrete components for both surface and underground transport systems. Under his scientific leadership, over 200 projects have been successfully developed and implemented, significantly contributing to the modernization of Ukraine’s rail infrastructure. His findings on the deformation mechanics of track elements and materials have become the foundation for optimizing the durability and safety of rail systems. An active member of ASME International and the International Academy of Scientific Discoveries and Inventions, Mr. Volodymyr Hovorukha’s research continues to influence railway engineering innovation and infrastructure development globally.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

  1. Hovorukha, V., Hovorukha, A., Sobko, T., & Semyditna, L. (2025). Reliability improvement of track infrastructure in open-pit rail transport. Geo-Technical Mechanics, (173), 38–48. https://doi.org/10.15407/geotm2025.173.038

  2. Hovorukha, V. V., & Hovorukha, A. V. (2023). Improvement of the service life of mining and industrial equipment by using friction modifiers. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (4), 74–82. https://doi.org/10.33271/nvngu/2023-4/074

  3. Hovorukha, V., Hovorukha, A., & Makarov, Y. (2022). Research on the dynamic processes of vehicles and an arbitrary configuration rail track, influencing the side wear of the rail head and wheel flange contact surfaces at different values of friction coefficient between them. IOP Conference Series: Earth and Environmental Science, 970(1), 012029. https://doi.org/10.1088/1755-1315/970/1/012029

  4. Hovorukha, V., Hovorukha, A., Sobko, T., & Semyditna, L. (2022). Method for studying spatial vibrations of a vehicle during its movement along the rail track on separate supports with elastic-dissipative and inertial properties. Geo-Technical Mechanics, (167), 52–60.

  5. Hovorukha, V., Hovorukha, A., Makarov, Y., Sobko, T., & Semyditna, L. (2023, November 14–16). Investigation of residual deformations in joint zones of track sections under curved track operation conditions. In Proceedings of the XXI International Conference of Young Scientists: Geotechnical Problems of Mineral Deposit Development (pp. 145–150). Dnipro, Ukraine.

Amin Reza Kalantari Khalil Abad | Engineering | Best Researcher Award

Published on by Forensic Scientist

Dr. Amin Reza Kalantari Khalil Abad | Engineering | Best Researcher Award

Iran University of Science and Technology | Iran

Dr. Amin Reza Kalantari Khalil Abad is a distinguished researcher and Lecturer in Industrial Engineering at Iran University of Science and Technology, Tehran, specializing in system optimization and sustainable supply chain design. He earned his Ph.D. in Industrial Engineering from Iran University of Science and Technology (2024), focusing on designing resilient horticultural supply chains under pest disruption, and holds an M.Sc. in Industrial Engineering (System Optimization) from Kharazmi University and a B.Sc. from Meybod University, Iran. His research expertise spans decision-making, operations research, mathematical modeling, and optimization, with emphasis on sustainable, resilient, and circular supply chain networks under uncertainty. Dr. Amin Reza Kalantari Khalil Abad has extensive teaching experience as a lecturer and teaching assistant in logistics, supply chain management, operations research, and software applications including GAMS and MiniTab. He has published six high-impact journal articles, including in the Journal of Environmental Management (2025), Journal of Industrial Information Integration (2025), Computers & Chemical Engineering (2024, 2023), Journal of Cleaner Production (2024), and Applied Soft Computing (2023). His work has been cited 57 times by 51 documents, achieving an h-index of 5 according to Scopus. Recognized as Top Ph.D. Student in Education (2021–2022) and Research (2023–2024), he also serves as a reviewer for leading journals and international conferences. Through his innovative research integrating optimization techniques, sustainable development, and supply chain resiliency, Dr. Amin Reza Kalantari Khalil Abad has significantly contributed to advancing both academic knowledge and practical applications, making him a highly deserving candidate for the Best Researcher Award.

Profile: Scopus | Google Scholar | ORCID | ResearchGate | LinkedIn

Featured Publications

  • Alizadeh, M., Kalantari Khalil Abad, A. R., Jahani, H., & Makui, A. (2023). Prevention of post-pandemic crises: A green sustainable and reliable healthcare supply chain network design for emergency medical products. Journal of Cleaner Production, 139702. https://doi.org/10.1016/j.jclepro.2023.139702

  • Kalantari Khalil Abad, A. R., Barzinpour, F., & Pishvaee, M. S. (2023). Toward circular economy for pomegranate fruit supply chain under dynamic uncertainty: A case study. Computers & Chemical Engineering, 178, 108362. https://doi.org/10.1016/j.compchemeng.2023.108362

  • Kalantari Khalil Abad, A. R., & Pasandideh, S. H. R. (2022). Green closed-loop supply chain network design with stochastic demand: A novel accelerated Benders decomposition method. Scientia Iranica, 29(5), 2578–2592. https://doi.org/10.24200/sci.2022.55657

  • Kalantari Khalil Abad, A. R., Barzinpour, F., & Pishvaee, M. S. (2023). Green and reliable medical device supply chain network design under deep dynamic uncertainty: A novel approach in the context of COVID-19 outbreak. Applied Soft Computing, 110964. https://doi.org/10.1016/j.asoc.2023.110964

  • Kalantari Khalil Abad, A. R., & Pasandideh, S. H. R. (2021). Green closed-loop supply chain network design: A novel bi-objective chance-constraint approach. RAIRO-Operations Research, 55(2), 811–840. https://doi.org/10.1051/ro/2021035

Valery Zakharov | Chemical Engineering | Excellence in Research Award

Published on by Forensic Scientist

Dr. Valery Zakharov | Chemical Engineering | Excellence in Research Award

Lomonosov Moscow State University | Russia

Dr. Valeriy Zakharov is a distinguished scientist whose career demonstrates a lifelong commitment to advancing the chemical sciences. His pioneering studies in coordination chemistry, spectroscopy, and photophysical processes have shaped the understanding of molecular structures and photoactive systems. Throughout his career, he has collaborated with leading researchers, delivered influential conference presentations, and authored numerous impactful publications. His research stands at the intersection of fundamental science and applied innovation, making him one of the most respected contributors to the global scientific community.

Professional Profile

Scopus

Google Scholar

ORCID

Education

Dr. Valeriy Zakharov pursued his higher education in chemistry at Lomonosov Moscow State University, where he specialized in physical and inorganic chemistry. His graduate research was devoted to coordination compounds and their photophysical behavior in complex environments. During his doctoral training, he mastered advanced spectroscopic techniques and theoretical approaches, providing him with the expertise to investigate light-sensitive systems and molecular structures. The strong academic foundation he established at the university became the cornerstone of his later achievements in both theoretical and experimental chemistry.

Experience

In his professional career, Dr. Valeriy Zakharov has held teaching and research responsibilities at Lomonosov Moscow State University, where he consistently combined academic rigor with scientific creativity. His early work focused on electron microscopy of silver halide systems, exploring the mechanisms of latent image formation in photographic materials. He later expanded his research into optically detected magnetic resonance and low-temperature phosphorescence of coordination compounds, broadening the scope of spectroscopic studies. He has been actively involved in both national and international collaborations, ensuring that his findings reached a global audience and promoting cross-disciplinary scientific exchange.

Research Interests

Dr. Valeriy Zakharov’s research interests cover a wide spectrum of modern chemistry. He has dedicated much of his work to understanding the structural and photophysical properties of coordination compounds, with special attention to the triplet states of transition metal complexes. His investigations of silver halide systems provided new insights into photographic sensitivity, image formation, and the fundamental processes of photochemistry. He has also made significant contributions to optically detected magnetic resonance spectroscopy and its applications to metal complexes and rare-earth elements. In addition, his studies on surface-enhanced Raman scattering have advanced the understanding of molecular interactions on colloidal silver surfaces, creating new opportunities for nanomaterials research and applied spectroscopy.

Awards

Dr. Valeriy Zakharov has been widely recognized for his exceptional contributions to chemistry and spectroscopy. His innovative approaches to studying photoactive materials and the development of advanced spectroscopic techniques have earned him high regard in both academic and applied sciences. The nomination for the Excellence in Research Award in Scientific Research highlights his lasting influence, his role in advancing scientific knowledge, and his dedication to training and inspiring the next generation of chemists.

Publications

Dr. Valeriy Zakharov has authored numerous scholarly works that have advanced the fields of spectroscopy, coordination chemistry, and photophysics. His publications include influential articles in highly respected journals and collaborative studies with leading scientists. A few notable examples include:

  • Surface-enhanced raman scattering of 2, 2′-bipyridine adsorbed on colloidal silver and stabilized AgBr sols
    Journal of Colloid and Interface Science
    Published on: 1993
    Citation: 42

  • Surface tension of silver in different media
    Journal of Physics and Chemistry of Solids
    Published on: 1993
    Citation: 29

  • Photoluminescent silicon nanocrystals stabilized by ionic liquid
    Journal of Nanoparticle Research
    Published on: 2011
    Citation: 24

  • Low-temperature phosphorescence and ODMR study of 2, 2′-bipyridine and Rh (bpy) 3+ 3
    Chemical Physics Letters
    Published on: 1987
    Citation: 23

  • The crystal and molecular structure of complex Gd (NO3)(phen) 2
    Russian Journal of Coordination Chemistry
    Published on: 1991
    Citation: 22

  • Stabilization of silicon nanoparticles by carbenes
    Russian Journal of Coordination Chemistry
    Published on: 2010
    Citation: 20

  • The isolated flat silicon nanocrystals (2D structures) stabilized with perfluorophenyl ligands
    Journal of Nanoparticle Research
    Published on: 2014
    Citation: 18

Conclusion

Dr. Valeriy Zakharov has dedicated his career to advancing the chemical sciences, producing research that is both pioneering and enduring in its influence. His work has provided clarity to complex spectroscopic phenomena, expanded the knowledge of photoactive coordination compounds, and opened new avenues in photochemistry and nanomaterials. His dedication to scientific excellence, collaborative spirit, and prolific contributions make him a highly deserving candidate for the Excellence in Research Award in Scientific Research at Lomonosov Moscow State University.

 

Xinxin Wang | Engineering | Best Researcher Award

Published on by Forensic Scientist

Mr. Xinxin Wang | Engineering | Best Researcher Award

North China Electric Power University | China

Xinxin Wang is a driven and innovative PhD candidate at North China Electric Power University, whose work bridges advanced theoretical research with practical engineering solutions. With a strong foundation in machinery and power engineering, he has developed expertise in the design, analysis, and optimization of underground tunneling equipment, particularly Tunnel Boring Machines (TBMs). His career reflects a deep commitment to solving complex challenges in rock mechanics and engineering, supported by collaborative efforts with leading experts in China and abroad. His predictive models and design methods have significantly advanced tunneling efficiency, making him a promising leader in his field.

Professional Profile

Scopus

ORCID

Education

Xinxin Wang earned a Master’s degree in Machinery and Engineering from Inner Mongolia University of Science and Technology, followed by doctoral studies in Power Machinery and Engineering at North China Electric Power University. Selected for the prestigious National “Excellent Engineer Program,” he broadened his academic exposure through a joint doctoral program as a visiting scholar at the University of Pisa, Italy. This international engagement allowed him to integrate advanced European engineering practices with domestic innovation, enriching his academic and professional capabilities in tunneling technology and rock-breaking mechanics.

Experience

Xinxin Wang has actively participated in multiple national-level research projects, including those funded by the National Natural Science Foundation of China and the National High Technology Research and Development Program. His contributions extend to the development of proprietary software for calculating rock-breaking forces in TBM disc cutters and the creation of new cutterhead designs capable of handling varied geological conditions. He works closely with industry and academic partners to ensure his research outcomes are implemented in real-world projects, thus enhancing the efficiency, reliability, and cost-effectiveness of large-scale underground excavation.

Research Interest

His research focuses on intelligent control systems and energy efficiency analysis for advanced underground construction equipment, particularly TBMs. He is deeply engaged in studying the collaborative rock-breaking mechanism of disc cutters, developing predictive models for cutter forces and cutterhead torque, and designing innovative solutions to optimize performance in diverse geological settings. Additionally, his expertise spans rock mechanics, structural analysis, and the integration of advanced computational modeling techniques into engineering practice.

Awards

Xinxin Wang has received recognition for his scholarly achievements through competitive doctoral scholarships and honors for academic excellence. His innovative contributions to TBM rock-breaking mechanics, cutterhead design, and excavation efficiency have been widely acknowledged in professional circles. These recognitions underscore his potential to make sustained and transformative contributions to the tunneling and underground engineering sector, making him a strong candidate for the Best Researcher Award.

Publications

Title: Investigation into the Rock-Breaking Forces of TBM Disc Cutters with Diverse Edge Shapes
Journal: Rock Mechanics and Rock Engineering
Published on: 2025

Title: Study on the Rock-Breaking Forces of TBM Disc Cutters with Uneven Wear
Journal: Chinese Journal of Theoretical and Applied Mechanics
Published on: 2025

Title: Study on Fatigue Characteristics of High-Pressure Vessel with Multiple Cracks in Stages
Journal: Mechanical Design and Manufacturing
Published on: 2024

Title: Allowable Limit of Crack Defect Zone Evaluation under Expected Life of Ultra-high Pressure Vessel Head
Journal: Thermal Processing Technology
Published on: 2024

Conclusion

By combining theoretical innovation with real-world engineering solutions, Xinxin Wang has made impactful contributions to the science and technology of tunnel boring and underground excavation. His research has not only improved operational efficiency but has also reduced construction costs and enhanced safety in challenging environments. With proven academic excellence, international collaboration experience, and a strong record of published work, he exemplifies the qualities of a dedicated and forward-thinking researcher worthy of the Best Researcher Award.

Karim Heydari | Engineering | Best Researcher Award

Published on by Forensic Scientist

Dr. Karim Heydari | Engineering | Best Researcher Award

Isfahan University of Technology | Iran

Dr. Karim Heydari is a distinguished scientist and academic in the field of textile engineering and polymer science, renowned for his expertise in developing sustainable and high-performance polymer composites. His research has been instrumental in transforming recycled polyethylene terephthalate (PET) into advanced textile fibers with improved mechanical integrity, flame resistance, and processability. Through innovative use of nanotechnology, eco-friendly flame-retardant systems, and molecular chain extenders, Dr. Heydari has contributed significantly to bridging environmental sustainability with industrial-scale manufacturing. His dedication to advancing polymer recycling technologies positions him as a leading figure in sustainable materials research.

Professional Profile

ORCID

Education

Dr. Heydari holds a strong academic background in textile engineering, polymer processing, and materials science, with specialized training in fiber manufacturing technologies, rheological property analysis, and nanocomposite engineering. His educational journey has provided him with a unique interdisciplinary skill set, enabling him to address challenges in polymer degradation, fiber spinning, and additive compatibility with scientifically sound and technologically viable solutions.

Experience

Throughout his career, Dr. Heydari has led and collaborated on multiple high-impact research projects focused on the optimization of recycled polymers for advanced textile applications. His work encompasses the full material development chain from feedstock selection and additive formulation to reactive extrusion, melt spinning, and product testing. He has applied advanced analytical techniques such as scanning electron microscopy, X-ray diffraction, thermogravimetric analysis, and rheological characterization to evaluate and enhance composite performance. In addition to academic publications, Dr. Heydari has actively collaborated with industrial partners to translate laboratory innovations into production-ready materials, particularly for applications demanding both performance and environmental compliance.

Research Interest

Dr. Heydari’s research interests cover a broad range of topics in sustainable material science, including polymer recycling and upcycling, flame-retardant fiber composites, nano clay dispersion technologies, rheology-driven process optimization, and environmentally friendly additive systems. He is particularly passionate about valorizing multiple-recycled PET often considered unsuitable for high-quality applications  by restoring its molecular architecture and enhancing its functional properties. His research is driven by the goal of creating textile fibers that meet rigorous mechanical, thermal, and safety standards without compromising ecological responsibility.

Awards

Dr. Heydari has gained recognition for his pioneering contributions to sustainable polymer technology and textile engineering. His innovative approach to combining zinc phosphinate flame retardants, Cloisite 30B nanoclay, and multifunctional epoxy-based chain extenders has resulted in composites with exceptional flame resistance, thermal stability, and spinnability. These advancements not only contribute to safer and more durable textile products but also support global sustainability initiatives. His ability to merge scientific innovation with industrial applicability makes him a highly deserving candidate for the Best Researcher Award.

Publications

Dr. Karim Heydari has contributed impactful research on the rheological, thermal, and mechanical enhancement of recycled polyethylene terephthalate (PET) composites, with a focus on flame retardancy and spinnability.

Title: Enhanced Spinning Properties of Chain‐Extended Flame‐Retarded Multiple‐Recycled PET/Cloisite 30B Nanocomposite
Journal: Journal of Applied Polymer Science
Published on: August 2025

Title: Rheological Probing Molecular Weight Increase in Flame Retarded Doubly Recycled PET in the Presence of Nanoclay and Investigating its Spinnability
Journal: Preprint
Published on: January 2025

Conclusion

Dr. Karim Heydari’s contributions to polymer recycling and textile engineering represent a significant step forward in the creation of sustainable, high-performance materials. His work addresses urgent environmental challenges associated with polymer waste while providing viable solutions for industrial fiber production. By integrating advanced material science with practical manufacturing processes, he continues to influence the fields of textile engineering, polymer technology, and sustainable manufacturing. His research not only pushes the boundaries of scientific understanding but also demonstrates a commitment to creating eco-conscious innovations that can be adopted across global industries.

Shushen Ye | Engineering | Best Researcher Award

Published on by Forensic Scientist

Mr. Shushen Ye | Engineering | Best Researcher Award

Huaqiao University – Xiamen Campus | China

Shushen Ye is a dedicated graduate student at the College of Civil Engineering, Huaqiao University, China. His academic journey reflects a focused pursuit of excellence in structural engineering, especially in the realm of vibration control. His research delves into nonlinear stochastic vibration mechanisms in high-pier structures, aiming to innovate solutions for real-world infrastructure challenges. With a strong foundation in hydraulic engineering and a keen interest in structural dynamics, Shushen Ye is poised to contribute significantly to the civil engineering research community.

Professional profile👤

ORCID

Strengths for the Awards✨

  1. Focused Research Topic: Shushen Ye is conducting research on a niche and highly relevant area—random vibration analysis and control of high-pier structures. This field has significant implications for structural safety in civil engineering, particularly in seismic and wind-prone areas.

  2. Publication in a Reputed Journal: He has successfully published a research article in the International Journal of Dynamics and Control (Springer), which is indexed and recognized in engineering fields. The publication demonstrates originality by proposing an innovative Nonlinear Energy Sink Inerter (NESI) that reduces mass requirements—an advancement over traditional vibration mitigation techniques.

  3. Clear Technical Contribution: The research contributes to solving a known engineering problem (mass inefficiency in NES) and offers potential for real-world application in structural design.

Areas for Improvement

  1. Limited Research Output: Currently, there is only one publication listed, and no record of other ongoing/completed projects, industry collaborations, or patents. This limits the evidence of sustained research productivity.

  2. Citation Metrics and Visibility: There are no details on citation indices, h-index, or broader academic reach (e.g., Google Scholar or ResearchGate profile). Building these would strengthen the nomination.

  3. Lack of Academic Engagement: There is no information on editorial roles, professional memberships, or collaborations. These are typically considered markers of engagement and recognition in the research community.

🎓 Education

Shushen Ye is currently pursuing a Master’s degree in Civil Engineering (Hydraulic Engineering) at Huaqiao University, Fujian, China, with expected graduation in 2025. His academic coursework and research training are rooted in structural analysis, dynamic response modeling, and advanced control methods for civil infrastructure.

👨‍🎓 Experience

As a graduate student, Shushen Ye has immersed himself in advanced research on the random vibration analysis and vibration control of high-pier structures. Although he has not yet been formally employed in consultancy or industry projects, his graduate work showcases a practical understanding of nonlinear energy control systems and provides significant insights into modern structural engineering problems.

🔬 Research Interest On Engineering

Shushen Ye’s primary research interests include Structural Nonlinear Stochastic Vibration and Control, particularly applied to high-pier bridge structures. His work emphasizes developing and analyzing novel energy dissipation systems, such as the Nonlinear Energy Sink Inerter (NESI), which demonstrates promise in enhancing vibration suppression with reduced mass requirements compared to traditional systems.

🏅 Award

Shushen Ye is nominated for the Best Researcher Award in recognition of his novel contribution to vibration control strategies in civil engineering. His work on the NESI system introduces a significant improvement in structural safety, marking an impactful beginning to his research career. This nomination underscores his potential to be a future leader in the field of structural dynamics and earthquake engineering.

📚 Publication

Shushen Ye has authored a research article in the International Journal of Dynamics and Control (Springer, 2025), titled “Vibration suppression of high-pier structures using NESI: A nonlinear approach”. This paper explores an innovative approach using the Nonlinear Energy Sink Inerter (NESI) and its effectiveness in controlling lateral vibrations of tall structures.
🔗 Read the full article here
📌 Cited by: The paper is newly published and is yet to accumulate citations, but its relevance to earthquake-resistant design makes it a valuable future reference.

🧩 Conclusion

Shushen Ye stands out as a young, enthusiastic researcher whose innovative contributions to structural vibration control are commendable. His dedication to solving complex civil engineering challenges through analytical modeling and energy-efficient systems highlights his commitment to sustainable infrastructure development. This award nomination is a testament to his academic promise and emerging impact in the field.