Jinbo Feng | Environmental and Sustainable Materials | Best Researcher Award

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Mr. Jinbo Feng | Environmental and Sustainable Materials | Best Researcher Award

Shenzhen University | China

Mr. Jinbo Feng is a researcher in architecture at Shenzhen University, China, whose work focuses on sustainable building design, environmental comfort, and material innovation. His research integrates architectural theory with environmental technology, emphasizing thermal comfort optimization, self-insulating concrete development, solid waste recycling, and bionic design for marine ecological restoration. He has co-authored peer-reviewed studies, including the SCI Q2 article “Climate-Responsive Design for Sustainable Housing: Thermal Comfort, Spatial Configuration, and Environmental Satisfaction in Subtropical Void Decks” published in Buildings, and presented at the 16th International Conference on Environment-Behavior Studies (CEB-ASC) on residents’ perception of settlement spaces. His ongoing projects involve the thermal comfort study of overhead spaces in subtropical residential buildings, finite element modeling of thermal and mechanical behavior in insulating blocks, and bionic polymer reef design under the Shenzhen–Hong Kong Joint Funding Programme. Recognized with the Shenzhen University Special Award Scholarship and other academic honors, Feng demonstrates a strong commitment to advancing low-carbon, resource-efficient architectural solutions. His work contributes to bridging the gap between design aesthetics, engineering functionality, and environmental sustainability, promoting innovative strategies for climate-responsive architecture in rapidly urbanizing subtropical regions.

Profile: ORCID

Featured Publications

  • Feng, J., & [Mentor’s Name]. (2024). Climate-responsive design for sustainable housing: Thermal comfort, spatial configuration, and environmental satisfaction in subtropical void decks. Buildings. (SCI Q2).

  • Feng, J., & [Mentor’s Name]. (2024). A study of the correlation between the form of public space in settlements and the evaluation of residents’ perceptions. In Proceedings of the 16th International Conference on Environment-Behavior Studies (CEB-ASC), Nanjing University, China.

Spomenka Kobe | Environmental and Sustainable Materials | Distinguished Scientist Award

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Prof. Dr. Spomenka Kobe | Environmental and Sustainable Materials | Distinguished Scientist Award

The Jožef Stefan Institute | Slovenia

Prof. Dr. Spomenka Kobe is a distinguished materials scientist and one of Europe’s leading experts in nanostructured materials, magnetic materials, and sustainable alloy design. Her pioneering research has advanced the scientific understanding and technological innovation in rare-earth magnet technology, nanostructured thin films, and magnetic materials recycling. She played a pivotal role in establishing rare-earth magnet research in Slovenia, leading major national and European research programs on critical raw materials and sustainable magnet production. Her Scopus-indexed research portfolio includes 169 publications, which have collectively received 2,350 citations from 1,949 documents, reflecting an h-index of 22. Her work spans critical areas of magnetism, solid-state physics, thin-film engineering, and microstructural analysis, significantly influencing global research directions in advanced materials science. Prof. Dr. Spomenka Kobe’s scientific leadership is exemplified through her coordination of the FP7 European Project ROMEO (Replacement and Original Magnet Engineering Option) and the International Associated Laboratory PACS2 (Push-Pull AlloyS and Complex Compounds) in collaboration with CNRS, France. She has also been a principal investigator on numerous EU and national R&D projects and an active contributor to international academic and industrial innovation networks. Her applied research achievements include seven patents (four European patents), three innovations, and multiple technology transfers to industrial production, showcasing her ability to translate advanced materials research into practical applications. She has authored several book chapters, delivered numerous invited lectures, and contributed to major international conferences on magnetic and nanostructured materials.

Profiles: Scopus | ResearchGate | LinkedIn

Featured Publications

• Schieren, L., Semsari Parapari, S., Tomše, T., Žužek, K., Šturm, S., Kobe, S., & Burkhardt, C. (2025). Evaluating citric acid as a selective leaching agent to extract Nd₂Fe₁₄B matrix phase from end-of-life magnets. Journal of Rare Earths, 43(7). https://doi.org/10.1016/j.jre.2025.04.020

• Grau, L., Moreno López, R., Kubelka, P., Burkhardt, F., Tomše, T., Kobe, S., & Burkhardt, C. (2024). Effects of thermal demagnetization in air on the microstructure and organic contamination of NdFeB magnets. Materials, 17(22), 5528. https://doi.org/10.3390/ma17225528

• Tomše, T., Burkhardt, F., Krasniqi, L., Ivekovič, A., Kocjan, A., Kobe, S., Podmiljšak, B., Burkhardt, C., Šturm, S., & Žužek Rožman, K. (2024, September). An alternative sintering strategy for anisotropic Nd–Fe–B magnet based on recycled content. International Materials Science and Engineering Congress (MSE 2024).

• Grau, L., Fleissner, P., Kobe, S., & Burkhardt, C. (2024). Processability and separability of commercial anti-corrosion coatings produced by in situ hydrogen-processing of magnetic scrap (HPMS) recycling of NdFeB. Materials, 17(11), 2487. https://doi.org/10.3390/ma17112487

• Tomše, T., Podmiljšak, B., Scherf, L. M., Kessler, R., Kobe, S., Kocjan, A., Šturm, S., & Žužek Rožman, K. (2024). Unravelling the intricacies of micro-nonuniform heating in field-assisted sintering of multiphase metallic microstructures. Journal of Materials Processing Technology. https://doi.org/10.1016/j.jmatprotec.2024.118405

Danladi Abdu | Engineering | Best Researcher Award

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Mr. Danladi Abdu | Engineering | Best Researcher Award

Federal University of Transportation | Nigeria

Mr. Danladi Abdu is a distinguished civil engineering researcher whose work integrates artificial intelligence, data science, and structural engineering to advance the safety and performance of transportation infrastructures. His research focuses on the intelligent assessment and predictive modeling of structural behavior in railway and bridge systems using machine learning algorithms. Through his influential publications in reputable journals such as Structures and the Journal of Railway Science and Technology, Mr. Danladi Abdu has contributed significantly to the development of AI-based approaches for monitoring bridge pier settlements and predicting fire-induced steel beam deformations. His scholarly work bridges the gap between traditional structural analysis and modern computational intelligence, offering innovative methodologies for structural health monitoring and predictive maintenance. Mr. Danladi Abdu’s research interests encompass smart infrastructure systems, railway bridge engineering, machine learning applications in civil engineering, and sustainable design innovations. Recognized for his academic excellence and innovative mindset, he has received multiple awards, including the Class of 2023 Outstanding International Graduate Student Award from Central South University and the Aier Cup Innovation and Entrepreneurship Competition Award. His contributions highlight a strong commitment to applying advanced technologies for solving complex engineering challenges, fostering safer, more efficient, and sustainable infrastructure systems. With an expanding research portfolio and a growing impact in structural and transportation engineering, Mr. Danladi Abdu continues to drive forward-thinking solutions that merge artificial intelligence with civil engineering principles to enhance infrastructure reliability and sustainability in a rapidly evolving technological landscape.

Profile: ORCID

Featured Publications

  • Abdu, D. M., Shedamang, S., Jimoh, J., & Idris, A. (2025). Prediction of fire-induced steel beam deformation using machine learning algorithms. Journal of Railway Science and Technology. https://doi.org/10.1016/j.jrst.2025.10.001

  • Abdu, D. M., Guo, W., & Wang, Y. (2023). Assessment of railway bridge pier settlement based on train acceleration response using machine learning algorithms. Structures. https://doi.org/10.1016/j.istruc.2023.03.167

Bojiang Yin | Engineering | Best Researcher Award

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Mr. Bojiang Yin | Engineering | Best Researcher Award

School of Petrochemical Engineering, Lanzhou University of Technology | China

Mr. Bojiang Yin’s research primarily focuses on the fundamental and applied aspects of special valve design and process systems, with an emphasis on structural parameter optimization, reliability engineering, and multi-physics coupling dynamics. His work addresses critical challenges in extreme operating environments, such as ultra-low temperature liquid hydrogen systems, by developing innovative sealing structures and evaluating their performance using advanced computational approaches. He has employed techniques including thermo-mechanical coupling, sensitivity analysis, high-precision RBF surrogate modeling, and NSGA-II optimization to achieve reliable bidirectional sealing under cryogenic conditions. Bojiang has published in high-impact journals like Scientific Reports, contributing to the scientific understanding of valve mechanics and optimization methodologies. He has collaborated with the National Natural Science Foundation of China, the Double First-Class Key Program of Gansu Province, and other regional technology programs, bridging academic research with practical industry applications. His contributions extend to consultancy projects, product development, and providing references for the design of advanced butterfly valves, positioning him as an emerging researcher in valve innovation and cryogenic system reliability.

Profile: ORCID

Featured Publications

Li, S., Yin, B., Wei, C., Li, W., & Yang, L. (2025). Structural analysis and multi-objective optimization of sealing structure for cryogenic liquid hydrogen triple-offset butterfly valve. Scientific Reports, 15, Article 20095. https://doi.org/10.1038/s41598-025-20095-6

Sarat Mohapatra | Engineering | Innovative Research Award

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Dr. Sarat Mohapatra | Engineering | Innovative Research Award

Centre for Marine Technology and Ocean Engineering (CENTEC), Instituto Superior Técnico, University of Lisbon | Portugal

Dr. Sarat Mohapatra is an accomplished marine researcher whose work bridges theoretical modeling, computational simulation, and experimental validation in the fields of hydroelasticity, ocean hydrodynamics, offshore aquaculture systems, and floating platform dynamics. His research primarily addresses complex fluid–structure interactions and the development of hydroelastic models for flexible and porous marine structures under combined wave and current conditions. With over 70 international publications in leading journals such as Ocean Engineering, Applied Ocean Research, Journal of Fluids and Structures, Physics of Fluids, and Journal of Marine Science and Engineering, his work has received significant global recognition, reflected in an h-index of 21 and more than 1,160 citations. Dr. Sarat Mohapatra has been a key contributor to several European and Portuguese Foundation for Science and Technology (FCT)-funded projects, focusing on hydrodynamic and hydroelastic analysis of large floating structures and wave energy systems. His recent studies include the development of analytical, numerical, and CFD-based models to predict wave-current interactions and improve the design of sustainable marine systems. In addition to his strong publication record, he has served as a journal reviewer, editorial contributor, and co-supervisor for doctoral and postgraduate research, promoting innovation and collaboration within marine technology. Through his pioneering contributions, Dr. Sarat Mohapatra continues to advance the understanding of ocean engineering phenomena, supporting innovations in marine renewable energy, offshore structure design, and environmentally resilient aquaculture technologies that contribute to the sustainable utilization of ocean resources.

Profiles: Scopus | Google Scholar | ORCID | ResearchGate | Cienciavitae

Featured Publications

  • Mohapatra, S. C., Amouzadrad, P., & Guedes Soares, C. (2025). Recent developments in the nonlinear hydroelastic modeling of sea ice interaction with marine structures. Journal of Marine Science and Engineering, 13(8), Article 1410. https://doi.org/10.3390/jmse13081410

  • Mohapatra, S. C., & Guedes Soares, C. (2025). Oblique wave analysis under current conditions on a floating flexible membrane. Physics of Fluids, 37(7), Article 072101. https://doi.org/10.1063/5.0278003

  • Mohapatra, S. C., Guedes Soares, C., & Meylan, M. H. (2025). Three-dimensional and oblique wave-current interaction with a floating elastic plate based on an analytical approach. Symmetry, 17(6), Article 831. https://doi.org/10.3390/sym17060831

  • Amouzadrad, P., Mohapatra, S. C., & Guedes Soares, C. (2025). Review on sensitivity and uncertainty analysis of hydrodynamic and hydroelastic responses of floating offshore structures. Journal of Marine Science and Engineering, 13(6), Article 1015. https://doi.org/10.3390/jmse13061015

  • Mohapatra, S. C., & Guedes Soares, C. (2025). Wave–current interaction with a deformable bottom in a three-dimensional channel. Physics of Fluids, 37(5), Article 052104. https://doi.org/10.1063/5.0267255

Nadiia Kopiika | Engineering | Best Paper Award

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Dr. Nadiia Kopiika | Engineering | Best Paper Award

University College London | United Kingdom

Dr. Nadiia Kopiika is a distinguished civil and structural engineering researcher whose work unites innovation, sustainability, and resilience in the reconstruction of critical infrastructure. She is affiliated with University College London, London, United Kingdom, and serves as a BA/CARA Research Fellow at the University of Birmingham (UK) and Teaching Assistant at Lviv Polytechnic National University (Ukraine). Dr. Nadiia Kopiika has made exceptional contributions to developing advanced methodologies for damage assessment, probabilistic modelling, and structural rehabilitation of reinforced concrete structures. Her publication, “Probabilistic Assessment of RC Beams with Corroded Thermally Strengthened Reinforcement” (Structures, 2025), presents a comprehensive probabilistic framework for evaluating the reliability and residual capacity of corroded reinforcement systems, providing crucial insights for sustainable and data-driven restoration. According to Scopus, she has authored 34 indexed publications, accumulated 416 citations across 219 citing documents, and holds an h-index of 15, reflecting her growing impact in the global engineering community. Her work seamlessly combines analytical precision with practical applications in infrastructure resilience and recovery. Dr. Kopiika is also actively engaged in collaborative initiatives such as bridgeUkraine.org and MetaInfrastructure.org, advancing digital diagnostics, AI integration, and circular design for post-disaster reconstruction. Her achievements have been recognised through prestigious honours, including the Award of the Verkhovna Rada of Ukraine for Young Scientists (2024) and the BA/CARA Research Fellowship (2023–2026). Through her interdisciplinary research and commitment to sustainable engineering, Dr. Nadiia Kopiika continues to advance innovative frameworks for resilient, future-ready infrastructure systems worldwide.

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

Featured Publications

  • Blikharskyy, Y., Kopiika, N., Khmil, R., Selejdak, J., & Blikharskyy, Z. (2022). Review of development and application of digital image correlation method for study of stress–strain state of RC structures. Applied Sciences, 12(19), 10157. [Cited by 56]
    https://doi.org/10.3390/app121910157

  • Kopiika, N., Karavias, A., Krassakis, P., Ye, Z., Ninic, J., Shakhovska, N., … (2025). Rapid post-disaster infrastructure damage characterisation using remote sensing and deep learning technologies: A tiered approach. Automation in Construction, 170, 105955. [Cited by 27]
    https://doi.org/10.1016/j.autcon.2025.105955

  • Blikharskyy, Y., Vashkevych, R., Kopiika, N., Bobalo, T., & Blikharskyy, Z. (2021). Calculation residual strength of reinforced concrete beams with damages, which occurred during loading. IOP Conference Series: Materials Science and Engineering, 1021(1), 012012. [Cited by 32]
    https://doi.org/10.1088/1757-899X/1021/1/012012

  • Blikharskyy, Y., Selejdak, J., & Kopiika, N. (2021). Corrosion fatigue damages of rebars under loading in time. Materials, 14(12), 3416. [Cited by 31]
    https://doi.org/10.3390/ma14123416

  • Blikharskyy, Y., Selejdak, J., Kopiika, N., & Vashkevych, R. (2021). Study of concrete under combined action of aggressive environment and long-term loading. Materials, 14(21), 6612. [Cited by 30]
    https://doi.org/10.3390/ma14216612

Weimin Huang | Engineering | Best Researcher Award

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Assist. Prof. Dr. Weimin Huang | Engineering | Best Researcher Award

Shandong University of Science and Technology | China

Dr. Weimin Huang, Academic Associate Professor at the College of Mechanical and Electronic Engineering, Shandong University of Science and Technology, is a leading expert in mechanical manufacturing and automation, with a focus on high-speed cutting technology, friction and fatigue wear mechanisms, and advanced agricultural machinery design. He earned his Ph.D. in Mechanical Manufacturing and Automation from Shandong University, establishing a strong foundation for his research and academic contributions. Dr. Weimin Huang has successfully led over 10 major research projects, including funding from the National Natural Science Foundation of China, and the Natural Science Foundation of Shandong Province, and has directed more than 20 industry-sponsored consultancy projects, effectively translating scientific insights into practical engineering solutions. His pioneering work on surface texture preparation via ball-end milling has significantly enhanced wear resistance and tribological performance of mechanical components, while his studies on sliding fatigue wear mechanisms have improved the durability and efficiency of industrial and agricultural equipment. He has published 37 Scopus-indexed journal articles, with 311 citations and an H-index of 11. Through his sustained research, innovation, and applied engineering contributions, Dr. Weimin Huang has established himself as a prominent scholar and a driving force in advancing mechanical manufacturing technologies.

Profile: Scopus

Featured Publications

1. Wang, G., Li, H., Wang, Z., & Jiang, D. (2025, May). Research on surface integrity and corrosion performance in high-speed ball-end milling of NiTi shape memory alloys.

2. Yang, J., Gong, C., Li, A., & Wang, P. (2025, March). Research on NiTi shape memory alloy electrolyte based on optimization of corrosion performance.

3. Huang, W., Huang, Y., Li, A., & Wang, G. (2024, November). Generation mechanism and anti-friction effect evaluation of continuous micro-groove texture machined by ball-end milling process.

4. Gao, L., Zhou, X., Huang, W., & Xia, H. (2024, February). Generation method and antifriction performance evaluation of discrete micro-pit surface texture based on high speed ball-end milling process.

5. Wang, G., Gong, C., Yang, J., & Wang, P. (2024, February). Electrochemical reaction mechanism of milled surface of NiTi shape memory alloy.

6. Gao, L., Wang, J., Huo, H., & Wang, Z. (2024, February). Residual height of surface topography in milling nickel-titanium shape memory alloy using a small-diameter cutter.

Tian Zhang | Engineering | Best Researcher Award

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Dr. Tian Zhang | Engineering | Best Researcher Award

Xi’an University of Architecture and Technology | China

Dr. Zhang Tian, a Master’s student in Structural Engineering at Xi’an University of Architecture and Technology, has built an impressive academic and research profile distinguished by consistent excellence, leadership, and early scholarly impact. He completed his undergraduate studies at Huanghuai University, where he was recognized as a “Three Good Student” for four consecutive years, awarded multiple academic scholarships, and graduated as an Outstanding Graduate. His achievements also include winning the third prize in the Challenge Cup of the School of Civil Engineering and being honored as an Outstanding Communist Youth League Member, distinctions that reflect his ability to combine academic rigor with innovation and service. At the graduate level, he has continued to excel, receiving an academic scholarship in 2022–2023 while advancing research in seismic-resistant structures, sustainable construction materials, and structural design optimization, areas vital to the development of safe and environmentally responsible infrastructure. Despite being in the early stage of his research career, Dr. Zhang Tian has already made notable scholarly contributions, with 6 publications indexed in Scopus, accumulating 69 citations from 68 documents, and achieving an h-index of 5. These metrics demonstrate that his work is not only visible but also valued within the global academic community. Combining strong academic performance, proven research productivity, and a clear vision for advancing structural engineering, Dr. Zhang Tian exemplifies the qualities of an emerging scholar whose contributions are poised to strengthen the safety, resilience, and sustainability of modern construction.

Profile: Scopus

Featured Publications

Xu, Y., Xu, Z.-D., Hu, H., Guo, Y.-Q., Huang, X.-H., Zhang, Z.-W., Zhang, T., & Xu, C. (2025). Experiment, simulation, and theoretical investigation of a new type of interlayer connections enhanced viscoelastic damper. International Journal of Structural Stability and Dynamics, 25(5), Article 2550045.

Valery Zakharov | Chemical Engineering | Excellence in Research Award

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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.

 

Xiaohong Lu | Engineering | Best Researcher Award

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Prof. Dr. Xiaohong Lu | Engineering | Best Researcher Award

Dalian University of Technology | China

Prof. Dr. Xiaohong Lu is a distinguished academic and innovator in the field of mechanical engineering, currently serving as a Professor at the School of Mechanical Engineering, Dalian University of Technology, China. She is a senior researcher at the State Key Laboratory of High-performance Precision Manufacturing, where her work focuses on advanced manufacturing processes including micro-milling, high-speed machining, and friction stir welding. With over two decades of experience in research and academia, she has significantly contributed to the evolution of precision machining technologies through innovative research, interdisciplinary collaboration, and knowledge dissemination. Her dedication to mentoring, scientific excellence, and technological innovation has made her a respected figure both nationally and internationally.

Professional Profile

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Education

Prof. Dr. Xiaohong academic journey showcases a strong foundation in mechanical and electric engineering. She earned her Ph.D. from Dalian University of Technology, where she focused on research topics that would later become central to her academic career. Her Master of Science degree was obtained from Inner Mongolia Agricultural University, with emphasis on mechanical systems and engineering principles. She completed her Bachelor of Science in Mechanical Design, Manufacture, and Automation at Jilin University. These academic achievements have provided her with the theoretical knowledge and practical insight essential for driving innovation in engineering science.

Experience

Prof. Dr. Xiaohong career reflects a steady progression through academic ranks and a consistent commitment to research and education. She began as a Postdoctoral Researcher in Instrument Science and Technology at Dalian University of Technology, where she deepened her expertise in precision measurement and mechanical systems. She later served as a Lecturer and Associate Professor before being appointed as a full Professor. Her academic path also includes valuable international experience as a Visiting Scholar at the Georgia Institute of Technology in the United States, where she collaborated on research in high-performance machining and advanced manufacturing technologies. Throughout her career, she has successfully led numerous research projects, mentored graduate and undergraduate students, and contributed to the development of intelligent manufacturing solutions.

Research Interests

Prof. Dr. Xiaohong Lu multidisciplinary research addresses core challenges in modern manufacturing systems. Her key areas of interest encompass precision and micro-machining of difficult-to-machine materials, numerical simulation of cutting and milling processes, and measurement and control in friction stir welding. Additionally, she focuses on smart and automated mechanical manufacturing technologies, as well as computer-aided design and manufacturing (CAD/CAM) systems integrated with production engineering. Her research not only bridges theoretical frameworks with industrial applications but also drives the advancement of material performance, machining accuracy, and intelligent automation in manufacturing.

Awards & Honors

Prof. Dr. Xiaohong Lu has been the recipient of numerous prestigious awards that reflect her excellence in both scientific research and academic mentorship. She has guided students to achieve multiple top honors in national and regional mechanical engineering competitions, earning several first, second, and third prizes along with distinction awards for creative design. Her contributions to global engineering education were recognized with an international academic award from the British Institution of Mechanical Engineers. She has also received significant recognition for her innovation in intellectual property, including a first prize in a prominent patent award. Prof. Lu has been honored by national education authorities for her research in natural sciences and has earned accolades for her teaching performance and curriculum development. Her consistent success in both research leadership and student mentoring underscores her exceptional impact on the academic and engineering communities.

Publications

  • Title: Transit network design based on travel time reliability
    Journal: Transportation Research Part C: Emerging Technologies
    Published on: October 2014
    Citation: 243

  • Title: Design and implementation of lean facility layout system of a production line
    Journal: International Journal of Industrial Engineering: Theory, Applications and Practice
    Published on: June 2011
    Citation: 112

  • Title: Anisotropic sliding on dual-rail hydrophilic tracks
    Journal: Lab on a Chip
    Published on: March 2017
    Citation: 72

  • Title: Model for the prediction of 3D surface topography and surface roughness in micro-milling Inconel 718
    Journal: The International Journal of Advanced Manufacturing Technology
    Published on: October 2018
    Citation: 69

  • Title: Surface roughness prediction in ultrasonic vibration-assisted milling
    Journal: Journal of Advanced Mechanical Design, Systems, and Manufacturing
    Published on: August 2020
    Citation: 65

  • Title: Deflection prediction of micro-milling Inconel 718 thin-walled parts
    Journal: Journal of Materials Processing Technology
    Published on: February 2021
    Citation: 64

  • Title: The effect of cutting parameters on micro-hardness and the prediction of Vickers hardness
    Journal: Measurement
    Published on: May 2019
    Citation: 60

Conclusion

Prof. Dr. Xiaohong Lu exceptional academic journey, cutting-edge research, and impactful mentorship place her at the forefront of mechanical engineering innovation in China and beyond. Her contributions have not only advanced the scientific understanding of machining and manufacturing technologies but have also shaped the next generation of engineers through education and leadership. With numerous national projects, high-impact publications, and significant patents to her name, she is a strong and deserving nominee for leading research awards in science and engineering.