Prof. Ali Bahari | High-Performance Materials | Best Researcher Award

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Prof. Ali Bahari | High-Performance Materials | Best Researcher Award

University of Mazandaran | Iran

Prof. Ali Bahari is a distinguished Professor of Nanotechnology in the Department of Solid-State Physics at the University of Mazandaran, Iran, and is globally recognized as part of the World’s Top 2% of Scientists by Stanford University. He earned his Ph.D. in Physics and Nanotechnology from Odense University (SDU), Denmark, where he focused on nanostructural properties of materials, growth, characterization, and applications. Over the years, Prof. Bahari has made remarkable contributions in quantum technologies, nanoelectronics, nanostructured materials, metamaterials, organic and polymer devices, cyborg technologies, cement-based composites, and clean energy production. His interdisciplinary research integrates nanotechnology, condensed matter physics, and material science, producing highly impactful innovations for sustainable development. Prof. Bahari has supervised numerous doctoral and master’s students, guided cutting-edge projects, and collaborated with international researchers to advance the understanding of material properties at the atomic and nanoscale level. He is an active reviewer for several high-impact journals and has presented his work at global conferences, strengthening the bridge between academia and industry. His outstanding contributions to nanoelectronics, perovskite optoelectronics, and metamaterials research have set new benchmarks for future studies. His work on magnetic nanostructures and electrocatalysis has wide-ranging applications in medicine, renewable energy, and sensor development, marking him as a leading figure in contemporary nanoscience.

Profile: Google Scholar

Featured Publications

The injection of Ag nanoparticles on surface of WO3 thin film: enhanced electrochromic coloration efficiency and switching response

Synthesis and tuning of gold nanorods with surface plasmon resonance

Experimental and theoretical studies of ordinary Portland cement composites contains nano LSCO perovskite with Fokker-Planck and chemical reaction equations

Structural and dielectric characteristic of povidone–silica nanocomposite films on the Si (n) substrate

Enhanced absorption performance of carbon nanostructure based metamaterials and tuning impedance matching behavior by an external AC electric field

Prof. Dr. Byoung-Suhk Kim | High-Performance Materials | Best Researcher Award

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Prof. Dr. Byoung-Suhk Kim | High-Performance Materials | Best Researcher Award

Prof. Dr. Byoung-Suhk Kim is a distinguished professor at Jeonbuk National University in the Department of Organic Materials and Textile Engineering. With extensive international research experience, he has contributed significantly to the fields of polymer chemistry, carbon composite materials, and nanomaterials. His academic work spans energy nanomaterials, electrochemical systems, and functional materials, supported by impactful publications, editorial board memberships, and leadership in professional societies. His global collaborations and long-standing academic career highlight his influence in both research and education.

Prof. Dr. Byoung-Suhk Kim | Jeonbuk National University | South Korea

Profiles

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Education

Prof. Kim obtained his Ph.D. in Polymer Chemistry from Hokkaido University, following his Master of Science and Bachelor of Science in Textile Engineering from Jeonbuk National University. His academic foundation is deeply rooted in materials science, bridging textile engineering with polymer chemistry and advanced nanomaterials. This strong academic background has provided him with the interdisciplinary expertise necessary for leading-edge innovations in organic materials and energy systems.

Experience

Prof. Kim has held prestigious positions across top global institutions. He has worked as a professor at Jeonbuk National University, with joint appointments in the Department of Carbon Composite Materials Engineering and the JBNU-KIST School. His international career includes postdoctoral research at Sogang University, the University of Connecticut, and the Max Planck Institute for Polymer Research as a Humboldt Fellow. He also served as a global COE researcher in Japan, a visiting scholar at the University of Pennsylvania, and a senior researcher at Kumho Petrochemical. This trajectory reflects global academic recognition and industrial relevance.

Skills

Prof. Kim is highly skilled in polymer synthesis, nanomaterials engineering, and electrochemical energy applications. He has advanced expertise in developing carbon fibers, functional nanofibers, biosensors, hydrogels, and hybrid composites. His proficiency extends to electrochemical energy storage and conversion systems, electrocatalysts, and nanostructured films. Beyond technical expertise, he has significant leadership skills in research management, editorial responsibilities, and professional society governance, contributing to both academic and industrial advancements.

Professional Activities

Prof. Kim has received numerous recognitions for his research and professional service. He serves on editorial boards of several high-impact international journals, including Discover Nano, Nanomaterials, and Molecules, and holds key leadership positions in Korean professional societies. His involvement in technical committees, government advisory groups, and evaluation panels reflects his influence on scientific policy and research development. These roles complement his academic achievements and highlight his standing as a leader in the scientific community.

Research Focus

His research focuses on electrochemical energy storage and conversion systems, including the development of supercapacitors, electrocatalysts, and energy nanomaterials. He also works on high-strength carbon fibers, nanostructured composites, and biosensors, emphasizing applications in sustainable energy and advanced functional materials. His research integrates polymer chemistry with nanotechnology to create innovative solutions for energy and biomedical challenges. These efforts demonstrate both fundamental contributions and practical applications.

Publications

Insights into low-impurity activated carbon materials for supercapacitors with high-voltage and ultra-long cycle stability
Journal: Composites Part B: Engineering (2025)

Green synthesis of activated carbons from machine-made Hanji as carbon precursor for high-rate supercapacitor and excellent sensor applications
Journal: Journal of Industrial and Engineering Chemistry (2025)

Crosslinked Aromatic Polyimides for High-Performance Heat-Dissipation Materials
Journal: Journal of Polymer Science (2025)

Effect of impurities in different activated carbon materials and their in-depth electrochemical analysis in supercapacitor coin-cell devices with organic electrolyte
Journal: Journal of Materials Chemistry A (2025)

A Simple and Efficient Non-Noble Cathode Catalyst Based on Carbon Hollow Nanocapsules Containing Cobalt-Based Materials for Anion Exchange Membrane Water Electrolyzer
Journal: Small (2025)

Effect of Boron and Iron at Various Concentrations on the Catalytic Graphitization of the Polyacrylonitrile Derived from the Polymerization of Acrylonitrile
Journal: Inorganics (2025)

In-Situ Polymerization for Catalytic Graphitization of Boronated PAN Using Aluminum and Zirconium Containing Co-Catalysts
Journal: Inorganics (2025)

Electrochemical sensors: Advances in bio-waste derived carbon materials and their applications
Type: Book Chapter (2025)

Rational Design of Ultrahigh-Loading Ir Single Atoms on Reconstructed Mn─NiOOH for Enhanced Catalytic Performance in Urea-Water Electrolysis
Journal: Small (2024)

Conclusion

Prof. Dr. Byoung-Suhk Kim exemplifies academic excellence, research innovation, and professional leadership in materials science, polymer chemistry, and nanotechnology. His contributions to electrochemical energy systems, nanomaterials, and functional composites are of high scientific and societal value. With strong global collaborations, editorial responsibilities, and recognition in both academia and industry, he is an outstanding and deserving candidate for the Best Researcher Award.

Dr Mansour Nasrallah Abd EL-Salam | Mechanical Properties of Materials | Best Researcher Award

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Dr Mansour Nasrallah Abd EL-Salam | Mechanical Properties of Materials | Best Researcher Award

Dr. Mansour Nasrallah Abd EL-Salam is a lecturer in mathematics at the Higher Technological Institute, Egypt 📘🎓. He holds a Ph.D. in Differential Equations (2021) and an M.Sc. in Fluid Mechanics (2015) from Zagazig University 🧠🔢. His research focuses on nonlinear dynamical systems, vibration control, and oscillator models for engineering structures 🔧🌀. With 10+ journal publications and expertise in control theory and computational modeling, he contributes to innovations in civil and mechanical systems. He is also a skilled educator and active in academic development, training, and collaborative research 💡👨‍🏫📊.

Dr Mansour Nasrallah Abd EL-Salam, Higher Technological Institute, Egypt

Profile

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🎓 Education

Dr. Mansour holds a strong academic foundation in mathematics 📘🔢. He earned his Ph.D. in Pure Mathematics (Differential Equations) in 2021 from Zagazig University, Egypt 🎓🧠, with a thesis focused on controlling vibrations in nonlinear dynamical systems. His M.Sc. in Applied Mathematics (Fluid Mechanics) was awarded in 2015, where he studied vibration control under multi-force dynamics 🌊⚙️. He also holds a B.Sc. in Mathematics with distinction (Very Good) from the same institution, awarded in 2006 🧮🏅. His academic training reflects a blend of theoretical precision and engineering application excellence.

🧑‍🏫 Experience 

Dr. Mansour has over 15 years of teaching experience at the Higher Technological Institute, Tenth of Ramadan City, Egypt 🎓🇪🇬. He began as a Demonstrator (2009–2016), advanced to Assistant Lecturer (2016–2021), and is currently serving as a Lecturer (2021–Present) 🧑‍🏫📘. He has taught a wide range of core mathematics courses including Differential Equations, Numerical Methods, Advanced Calculus, and Statistical Analysis 📐📊🧮. His teaching blends theory and computation, equipping students with analytical and problem-solving skills vital for engineering and applied sciences ⚙️🔍📏.

🧑‍💻 Certifications 

Dr. Mansour has completed multiple professional certifications enhancing his academic, research, and digital competencies 🧠📚. His training includes teaching strategies, student evaluation, and course design through NAQAAE (2021) 🏫📈. He also completed the TOEFL Review Course and workshops on research promotion, plagiarism prevention, and scientific database management hosted by Elsevier and Zagazig University 🔍🧑‍💻. Skilled in tools like Microsoft Office, LaTeX, and SPSS, he effectively integrates technology into education and research 💻📊. These certifications reflect his commitment to excellence in both pedagogy and scholarly integrity.

🔍 Research Focus 

Dr. Mansour’s research is centered on the modeling and control of nonlinear dynamical systems 🌀🔧. He specializes in vibration suppression techniques for complex systems such as Rayleigh–Van der Pol–Duffing oscillators, suspended cables, and cantilever beams using advanced controllers like negative velocity feedback, positive position feedback, PD controllers, and nonlinear saturation methods ⚙️📉. His work targets real-world engineering applications including mechanical and structural systems, enhancing performance, stability, and resilience under external excitation 💡🏗️. His studies contribute significantly to modern control theory, stability analysis, and applied mathematics for engineering innovation 🔍📊.

📚 Publications

Effect of Negative Velocity Feedback Control on the Vibration of a Nonlinear Dynamical System
Journal: International Journal of Dynamics and Control (2023)

Negative Derivative Feedback Controller for Repressing Vibrations of the Hybrid Rayleigh−Van der Pol−Duffing Oscillator
Journal: Nonlinear Phenomena in Complex Systems (2022)

On Controlling of Vibrations of a Suspended Cable via Positive Position Feedback Controller
Journal: International Journal of Dynamics and Control (2022)

A Suitable Active Control for Suppression the Vibrations of a Cantilever Beam
Journal: Sound and Vibration (2022)

Behavior of a Hybrid Rayleigh–Van der Pol–Duffing Oscillator with a PD Controller
Journal: Journal of Applied Research and Technology (2022)

Prof Chunlai Wang | Mechanical Properties of Materials | Best Researcher Award

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Prof Chunlai Wang | Mechanical Properties of Materials | Best Researcher Award

Prof. Chunlai Wang is a renowned expert in rock mechanics and mining engineering at the China University of Mining & Technology, Beijing ⛏️🏫. He serves as Associate Director of the National Engineering Laboratory for efficient indium and tin resource use. A Ph.D. supervisor and recipient of the National Youth Science and Technology Award, he specializes in rockburst mechanisms, microseismic monitoring, and landslide prediction 📡🪨. His achievements include over 80 academic papers (45+ SCI), three books (one Springer monograph), and eight national invention patents 💡📚. A former visiting scholar at UBC, Prof. Wang advances safe and intelligent mining technologies 🌍🔬.

Prof Chunlai Wang, China University of Mining and Technology-Beijing, China

Profile

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🎓 Education 

Prof. Chunlai Wang earned his Ph.D. in Geological Engineering from the University of Science & Technology Beijing (2007–2011) 🎓🧱. His doctoral research focused on advanced rock mechanics and mining safety, laying a strong academic foundation for his career in geotechnical engineering and hazard prediction. Prior to his Ph.D., he pursued rigorous training in geological sciences and engineering principles, which equipped him with the analytical and technical expertise to address complex mining and seismic challenges 🪨📊. His academic path has been marked by excellence, innovation, and a commitment to solving real-world problems in earth science and engineering 🌍🔬.

🏫 Experience

Prof. Chunlai Wang has been serving at the China University of Mining and Technology, Beijing since 2011 🏫🇨🇳, where he holds the role of Deputy Director of the Department of Resources Engineering and is an esteemed Ph.D. Professor in rock mechanics, rockburst control, and microseismic monitoring 🪨📡💥. As part of the School of Energy and Mining Engineering, he leads research and teaching in advanced geotechnical systems, underground hazard prevention, and intelligent mining technologies ⚙️⛏️🧠. His position combines academic leadership, research excellence, and national-level project coordination, making him a pillar in China’s mining safety innovation landscape.

🏆 Honors and Achievements

Prof. Chunlai Wang has been honored with 7 major national and ministerial-level science and technology awards 🏆🎓, including the Second Prize of the State Scientific and Technological Progress Award (2010) for innovations in joint open-pit and underground mining. He has received multiple second prizes from the China Coal Industry Association and China Nonferrous Metals Industry Association for breakthroughs in deep soft rock support, zero-waste tailing technologies, and mechanized mining ⚙️⛏️. His special award from the China Gold Association underscores leadership in gold mining engineering. These accolades reflect his lasting impact on safe, efficient, and sustainable mining technologies 🌍

🔬 Research Leadership

Prof. Chunlai Wang has led and contributed to 11 major research projects focused on rockburst prediction, microstructural instability, and dynamic disaster control in deep mining 🪨📡⛏️. As principal investigator on multiple National Natural Science Foundation of China (NSFC) projects, he has pioneered early-warning systems, animal behavior-based disaster prediction, and energy modeling under dynamic loads. His work spans both national and provincial programs, including the National Key R&D Program and Eleventh Five-Year Plan. Prof. Wang’s expertise in deep mine safety, rock mechanics, and multi-source monitoring is advancing safer and more intelligent mining technologies 🔬🧠⚙️.

🛠️ Invention and Innovation 

Prof. Chunlai Wang holds five authorized national invention patents that address rock mass failure prediction, microseismic early warning, and disaster prevention in mining engineering 🛠️📡. His innovations include methods for detecting rockburst risks, systems for multi-point displacement monitoring, and energy-absorbing structures for mine goafs 🪨📉. Notably, he developed a vertical coal bunker blockage-clearing device, advancing mine safety and operational efficiency ⚙️🚧. These patented technologies represent a fusion of geotechnical insight, sensor integration, and engineering safety applications, making a significant impact on rock mechanics, mine hazard mitigation, and smart mining development ⛏️🔬.

🔬 Research Focus 

Prof. Chunlai Wang’s research is rooted in rock mechanics and mining safety engineering 🪨⚙️. He specializes in the mechanism of rockburst and its prediction, aiming to reduce catastrophic failures in underground mining ⛏️💥. His work on microseismic monitoring enables early warning and real-time control of geological hazards 📡📈. He also focuses on landslide prediction and support technologies, improving slope stability and infrastructure protection 🏞️🛠️. Integrating advanced modeling and monitoring, his research enhances operational safety, disaster prevention, and sustainable mining practices 🌍🔬. His innovations are critical to modern geotechnical and energy resource engineering.

📚 Publications

Crack Nucleation Mechanism of Rock Fracture
Authors: Chunlai Wang, Baokun Zhou, Chaoyang Zhu, Changfeng Li, Liang Sun
Journal: Engineering Fracture Mechanics (2025)

Infrared Temperature Distribution Characteristics and State Assessment Method of Sandstone Under Tension and Compression Stress
Authors: Changfeng Li, Chunlu Lan, Baokun Zhou, Chaoyang Zhu, Qiru Sui, Xiaolin Hou, Chunlai Wang
Journal: Infrared Physics & Technology (2024)

Optimization of Ore Pillar Recovery Based on Weighting Combined with Uncertainty Measurement Theory
Authors: Jun Qian, Wenqiang Xu, Chunlu Lan, Chunlai Wang, Changfeng Li, Qingjun Yu, Yuze Li, Yutao Tang, Jianwei Zhang, Guannan Wang
Journal: Journal of Geophysics and Engineering (2024)

Prediction and Critical Transition Mechanism for Granite Fracture: Insights from Critical Slowing Down Theory
Authors: Chun-lai Wang, Bao-kun Zhou, Chang-feng Li, Zhi-jie Wen, Zhi-an Bai, Chao-yang Zhu, Liang Sun, Xu-hui Xue, Peng Cao
Journal: Journal of Central South University (2024)

Temperature Response of Coal Fracture Induced by Three-Dimensional Stress Field
Authors: Chunlai Wang, Changfeng Li, Baokun Zhou, Liang Sun, Zhian Bai, Chaoyang Zhu, Guangjin Wang, Qiru Sui, Jinze Song
Journal: Measurement (2024)

Robustness of Rock Damage Regions Induced by Crack Nucleation
Authors: Yubo Liu, Chunlai Wang, Changfeng Li, Zhian Bai, Lin Huang, Kang Peng, Xuhui Xue, Peng Cao
Journal: International Journal of Geomechanics (2023)

Numerical Simulation Investigation on Parameter Optimization of Deep-Sea Mining Vehicles
Authors: Hongyun Wu, Wei Liu, Min Jiang, Changfeng Li, Jiangming Li, Bingzheng Chen, Chunlai Wang, Yuheng Chen
Journal: Chinese Journal of Mechanical Engineering (2023)