Iyakutti Kombiah | Materials Chemistry | Lifetime Achievement Award

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Dr. Iyakutti Kombiah | Materials Chemistry | Lifetime Achievement Award

Dr. Iyakutti Kombiah | SRM Institute of Science and Technology | India

Dr. Iyakutti Kombiah, an eminent physicist and computational materials scientist, has made outstanding contributions to condensed matter physics, nanomaterials, and energy storage research, with a career spanning over four decades. He obtained his M.Sc. and Ph.D. in Physics from the University of Madras, followed by postdoctoral research in quantum chemistry at Uppsala University, Sweden, supported by SIDA. He served as Lecturer at the University of Madras, Reader and Professor at Madurai Kamaraj University, and later as Professor Emeritus and CSIR Emeritus Scientist at SRM University. His pioneering expertise lies in computational design and experimental validation of nanomaterials for hydrogen storage, photovoltaics, and CO₂ conversion, demonstrated through his leadership of multiple AOARD and ONRG-funded international projects. A prolific scholar with over 229 publications, 1,804 citations, and an h-index of 24, his research continues to influence the fields of energy materials and quantum chemistry. Dr. Iyakutti has held visiting positions at leading institutions in Japan, Canada, and the USA, fostering global collaborations. His recent works (2020–2025) focus on graphene-based hydrogen storage, Heusler alloys, and 2D nanomaterials, combining density functional theory with experimental studies. Honored with CSIR and UGC Emeritus Fellowships, he remains a leading figure advancing computational and sustainable energy materials research in India and beyond.

Profile: ORCID  | Scopus 

Featured Publications

  • Iyakutti, K., Reji, R. P., Rajeswarapalanichamy, R., & Kawazoe, Y. (2025). DFT based computational investigation of 2D monolayer gold (Au)–the goldene. Computational Condensed Matter, 25, e01132.

  • Iyakutti, K., Reji, R. P., Jayan, S., AjayJawahar, K., Karthigeyan, A., Rajeswarapalanichamy, R., & Kawazoe, Y. (2025). Heterostructuring, electronic and hydrogen storage properties of boron, carbon, nitrogen based 2D nanomaterials – A DFT study. International Journal of Computational Materials Science and Engineering, 14(3), 2550028.

  • Iyakutti, K., Reji, R. P., Rajeswarapalanichamy, R., & Kawazoe, Y. (2025, February 26). DFT based computational investigation of 2D monolayer gold (Au)–the goldene. Preprint.

  • Kaliyaperumal, A., Periyasamy, G., Iyakutti, K., & Annamalai, K. (2024). Effect of a mesoporous NiCo₂O₄ urchin-like structure catalyzed with a surface oxidized LiBH₄ system for reversible hydrogen storage applications. RSC Advances, 14, 12345–12354.

  • Iyakutti, K., Reji, R. P., AjayJawahar, K., Lakshmi, I., Rajeswarapalanichamy, R., Surya, V. J., Karthigeyan, A., & Kawazoe, Y. (2024). Interaction of H, H₂, and MgH₂ with graphene and possible application to hydrogen storage—A density functional computational investigation. International Journal of Quantum Chemistry, 124(15), e27467.

 

 

 

Jean Geringer | Materials Chemistry | Best Researcher Award

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Prof. Dr. Jean Geringer | Materials Chemistry
| Best Researcher Award

Prof. Dr. Jean Geringer | Mines Saint-Etienne | France

Prof. Dr. Jean Geringer is a distinguished expert in biomaterials, tribocorrosion, and materials science with extensive academic and industrial experience. He earned his Ph.D. on fretting corrosion of biomaterials at the École Nationale Supérieure des Mines de Saint-Étienne and later obtained HDR certification in research management, mentoring multiple Ph.D. students and postdocs. He has contributed significantly to the understanding of wear and corrosion mechanisms in orthopedic implants, integrating experimental and theoretical approaches. Currently a professor in biomaterials and tribocorrosion, he has held senior research positions internationally and led entrepreneurial initiatives in implant materials. His work bridges fundamental science and practical applications, demonstrating excellence in innovation, leadership, and interdisciplinary research, making him highly suitable for the Best Researcher Award.

Professional Profile

ORCID | Scopus

Education

Prof. Dr. Jean Geringer academic foundation spans chemistry and materials science. He completed post-secondary preparatory studies in France, followed by a Master’s degree in chemical engineering from the École Nationale Supérieure de Chimie de Toulouse (ENSC-T). He earned a Master’s in materials science at ENSM Saint-Étienne, focusing on biomaterials and contact mechanics. Subsequently, he completed a Ph.D. on fretting corrosion of biomaterials with a French government grant at ENSM Saint-Étienne. Later, he achieved HDR (Habilitation à Diriger des Recherches) at Jean Monnet University, demonstrating research management capability by supervising multiple Ph.D. students and postdoctoral researchers. He also passed competitive national teaching examinations, including Agrégation and CAPES, reflecting a solid blend of scientific knowledge and pedagogical expertise.

Professional Experience

Prof. Dr. Jean Geringer has over two decades of academic and research experience in biomaterials, tribocorrosion, and implant engineering. He served as an assistant professor, later advancing to a full professor at ENSM Saint-Étienne, mentoring Ph.D. students and postdocs. He worked as a senior research fellow at Samara University and led entrepreneurial projects in implant materials. His early career included research assistantships in analytical chemistry and teaching roles across secondary schools, preparatory programs, and university laboratories. He has also held visiting scholar positions in the USA and Europe, enhancing international collaboration. His professional trajectory demonstrates a strong combination of teaching, research, and leadership, with expertise in experimental and theoretical studies of fretting corrosion, wear mechanisms, and implant surface treatments.

Awards 

Prof. Dr. Jean Geringer has received recognition for excellence in research, teaching, and scientific leadership. His HDR certification highlights his capability in supervising Ph.D. and postdoctoral researchers. He has been invited as a visiting scholar at prestigious institutions in the USA and Europe, reflecting international acknowledgment of his expertise. Additionally, he has successfully managed industrial collaborations and entrepreneurial projects in biomaterials for orthopedic implants. His numerous publications in high-impact journals underscore his contributions to the field of tribocorrosion, implant wear, and electrochemical studies. These achievements, combined with his active mentorship and innovation-driven approach, position him as a leading researcher in biomaterials, making him highly suitable for awards recognizing research excellence, leadership, and global impact.

Research Interests 

Prof. Dr. Jean Geringer research focuses on biomaterials, tribocorrosion, and the electrochemical behavior of metallic implants under physiological conditions. He investigates wear and fretting-corrosion mechanisms in orthopedic and dental implants, combining experimental analysis, electrochemical impedance spectroscopy, atomic force microscopy, and theoretical modeling such as the Point Defect Model. His work includes studying protein interactions, surface treatments, polymer-metal interfaces, and the long-term performance of implant materials. He also explores multiscale analysis to enhance implant durability, integrating nanomaterials, coatings, and advanced polymers. The research bridges fundamental understanding with clinical applications, aiming to improve implant longevity and biocompatibility. His innovative and interdisciplinary approach positions him as a thought leader in tribocorrosion and biomaterials science, contributing significantly to healthcare and materials engineering.

Publication Top Notes

  • Zirconia ageing is related to total hip arthroplasty aseptic loosening. A study of 45 retrieved zirconia heads
    Year: 2024

  • Nano/micro implant debris affect osteogenesis by chondrocytes: Comparison between ceramic and UHMWPE from hip walking simulator
    Year: 2022

  • Highly porous Ti as a bone substitute: Triboelectrochemical characterization of highly porous Ti against Ti alloy under fretting-corrosion conditions
    Year: 2021

Conclusion 

Prof. Dr. Jean Geringer  is an exemplary candidate for the Best Researcher Award. His research demonstrates originality, rigor, and tangible contributions to biomedical materials and tribocorrosion science. He combines experimental excellence with mentorship and international experience, producing work that advances both theory and practice. While minor improvements in collaboration, outreach, and computational integration could enhance his impact, his current achievements already reflect leadership, innovation, and influence in his field. Recognition through the Best Researcher Award would be well-justified, honoring both his scientific contributions and the meaningful real-world applications of his research in healthcare and materials engineering.

Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

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Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

Dr. Faranak Hatami , Computational Chemistry , PhD at University of massachuessetes Lowell, United States

Faranak Hatami (Fara) is a dedicated physicist and researcher specializing in molecular dynamics simulations, machine learning, and nuclear materials science. Currently pursuing her Ph.D. in Physics at the University of Massachusetts Lowell, she focuses on transport property analysis and multi-objective optimization for molecular systems like Tri-Butyl-Phosphate (TBP). Faranak holds two master’s degrees—one in Physics from UMASS Lowell, where she explored force fields for TBP, and another in Nuclear Engineering from Shahid Beheshti University, where she investigated radiation damage in metals. With a robust background in computational physics, AI, and advanced simulation tools, she has authored multiple publications across nuclear materials and computational chemistry. Her teaching experience spans both the U.S. and Iran, reflecting her passion for education. Beyond academia, she completed a research internship at the University of Montreal. Faranak’s work bridges fundamental physics and practical applications, contributing innovative insights to the fields of material science and chemical engineering.

Professional Profile : 

Google Scholar 

Summary of Suitability for Award:

Faranak Hatami is a highly suitable candidate for a “Best Researcher Award”. She demonstrates exceptional multidisciplinary expertise spanning physics, molecular dynamics, machine learning, and nuclear materials science. Her Ph.D. work at UMASS Lowell innovatively combines atomic-scale simulations with AI to optimize force field parameters for Tri-Butyl-Phosphate, addressing both fundamental science and practical applications.  She has authored several impactful publications in reputable journals and preprints, covering diverse topics from radiation damage in metals to machine learning models predicting thermodynamic properties. Her research portfolio includes complex computational modeling, multi-objective optimization, and advanced materials analysis. Additionally, Faranak’s teaching record and successful research internship in Canada reflect her commitment to knowledge dissemination and international collaboration. Her ability to merge computational physics with machine learning showcases originality and forward-thinking, key attributes for top research honors. Faranak Hatami embodies the qualities of a best researcher: scientific rigor, innovative thinking, multidisciplinary skillset, and impactful publications. Her contributions significantly advance computational methods in physical sciences and engineering, making her a strong and deserving candidate for a “Best Researcher Award”.

🎓Education:

 Faranak Hatami is completing her Ph.D. in Physics at the University of Massachusetts Lowell (2021–2025), with her thesis focused on transport property analysis and optimization of force field parameters for Tri-Butyl-Phosphate (TBP), combining atomic-scale simulations with machine learning. Prior to this, she earned her M.Sc. in Physics from the same university in 2023, where she conducted a comparative study of force fields for liquid TBP using molecular dynamics. Earlier, she obtained her M.Sc. in Nuclear Engineering from Shahid Beheshti University in Iran (2016), where she examined radiation damage effects on zirconium and iron grain boundaries through simulations. Her academic journey began with a B.S. in Electrical Engineering from Kurdistan University in 2013. Throughout her studies, Faranak has integrated advanced computational methods, AI, and experimental data analysis, building a multidisciplinary foundation that connects physics, materials science, and engineering disciplines.

🏢Work Experience:

Faranak Hatami brings diverse experience across research, teaching, and technical projects. At UMASS Lowell, she serves as a Teaching Assistant in Physics while pursuing her Ph.D., guiding students through complex concepts. Previously, she lectured on Computational Methods and Statistical Methods and Physics courses at Shahid Beheshti University between 2014 and 2018. Her research career includes an internship at the University of Montreal (2019–2021), exploring hydrogen’s effects on iron grain boundaries using the kinetic activation relaxation technique (k-ART). Faranak has led significant academic projects spanning molecular dynamics simulations, multi-objective optimization, and machine learning applications in material science. She has deep expertise in computational tools such as LAMMPS, MCNP, VASP, and Python-based AI frameworks. Her work reflects a unique blend of fundamental physics research, practical problem-solving, and advanced data analysis, contributing to fields like chemical engineering, nuclear materials, and computational modeling.

🏅Awards: 

 Faranak Hatami has built an impressive research portfolio during her academic career, reflected in multiple publications and conference presentations. While specific named awards were not explicitly listed in her profile, her contributions have earned her recognition through invited presentations such as at the AIChE Annual Meeting, showcasing her expertise in molecular dynamics simulations and force field optimization. Completing dual M.Sc. degrees in Physics and Nuclear Engineering highlights her dedication and academic excellence. Her selection as a research intern at the University of Montreal, working on advanced computational studies in materials science, further underscores her capability and esteem in her field. Through her multidisciplinary approach integrating AI, molecular modeling, and nuclear materials science, she stands out as a rising scholar contributing valuable insights to computational physics and chemical engineering. As she advances her Ph.D., she is poised for further accolades in research innovation and scientific community engagement.

🔬Research Focus:

 Faranak Hatami focuses her research on the intersection of molecular dynamics simulations, machine learning, and materials science. Her Ph.D. work centers on analyzing transport properties and optimizing force field parameters for Tri-Butyl-Phosphate (TBP) using multi-objective optimization algorithms like NSGA-II/III. She applies molecular dynamics to predict critical thermodynamic and transport properties, integrating neural networks for parameter tuning. Additionally, she explores AI-based classification of microscopy and atomic-scale images, blending physics with cutting-edge data science. Faranak’s earlier research in nuclear engineering examined radiation damage in metals such as zirconium and nickel, utilizing techniques like climbing image nudged elastic band (CI-NEB) for defect analysis. She’s also investigated hydration free energies, grain boundary behaviors, and primary knock-on atom (PKA) spectra in irradiated materials. Her work bridges computational physics with practical engineering challenges, advancing predictive models and simulation methods to better understand complex molecular and material systems.

Publication Top Notes:

Comparative Analysis of Machine Learning Models for Predicting Viscosity in Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 6

Quantification of Methane Hydration Energy Through Free Energy Perturbation Method

Comparison of Different Machine Learning Approaches to Predict Viscosity of Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 3

Properties of Tri-Butyl-Phosphate from Polarizable Force Field MD Simulations

Citations: 1

A Revision of Classical Force Fields for Tri-N-Butyl Phosphate Molecular Dynamics Simulations

Interaction of primary cascades with different atomic grain boundaries in α-Zr: An atomic scale study

Citations: 34

An energetic and kinetic investigation of the role of different atomic grain boundaries in healing radiation damage in nickel

Citations: 31

Mr. ROSHAN KUMAR | Materials Chemistry | Best Researcher Award

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Mr. ROSHAN KUMAR | Materials Chemistry | Best Researcher Award

Mr. ROSHAN KUMAR , Materials Chemistry , Senior Scientist at CSIR – National Metallurgical Laboratory, India

Dr. Roshan Kumar is a highly accomplished Senior Scientist at CSIR–National Metallurgical Laboratory, Jamshedpur. With an academic foundation from premier institutes like IIT Delhi and NIT Jamshedpur, he brings over a decade of research and industrial experience in materials science, mechanical design, and manufacturing. His expertise spans from engine integration design at Tata Motors to pioneering research in biodegradable implants, hydrogen energy, and advanced metallurgy at CSIR-NML. He is actively involved in national research projects including DRDO, DST, and CSIR initiatives. Known for his innovative thinking and multidisciplinary research capabilities, he has significantly contributed to the development of green hydrogen solutions and advanced manufacturing processes. Dr. Kumar is also a passionate advocate for technology-driven social change, participating in programs like Women Technology Park. With multiple publications in reputed international journals and awards to his credit, he continues to bridge academic excellence and applied engineering for societal advancement.

Professional Profile : 

Scopus 

Summary of Suitability for Award:

Dr. Roshan Kumar exemplifies the qualities of an outstanding researcher, with a strong academic background from premier institutions like IIT Delhi and NIT Jamshedpur, and over a decade of professional experience across industry and research. Currently a Senior Scientist at CSIR–National Metallurgical Laboratory, he has made significant contributions to materials research, particularly in biodegradable implants, hydrogen energy, computational modeling, and metal corrosion studies. His work bridges computational science with experimental materials design, reflecting innovation and societal relevance. Recognized with an All India Rank 3 in CSIR-NET and a Best Poster Award at an international hydrogen conference, he has authored impactful publications in high-ranking journals. His leadership in interdisciplinary CSIR and DST projects underscores his collaborative and forward-looking research approach. With a clear focus on materials science and clean energy, Dr. Kumar’s achievements demonstrate excellence, innovation, and real-world application. Dr. Roshan Kumar is highly suitable for the “Best Researcher Award”, given his exemplary track record in research innovation, publication impact, national-level project leadership, and meaningful contributions to sustainable and advanced technologies.

🎓Education:

Dr. Roshan Kumar’s educational journey showcases academic brilliance and technical depth. He earned his M.Tech in Design Engineering from Indian Institute of Technology (IIT) Delhi in 2015 with an impressive CGPA of 9.115, demonstrating strong command in mechanical design and computational engineering. He completed his B.Tech in Production Engineering and Management from NIT Jamshedpur in 2010, securing a GPA of 8.65, laying a robust foundation in manufacturing and production systems. His schooling reflects consistent academic performance with 72% in CBSE (2005) from VBCV, Jamshedpur, and 69.2% in Class X (2003) under the Jharkhand Board from SJS, Jamshedpur. His early academic achievements were further validated by an All India Rank 3 in CSIR-NET, earning him eligibility for the prestigious Shyama Prasad Mukherjee Fellowship (2013). This strong educational background has fueled his contributions to scientific research, innovation, and national R&D missions.

🏢Work Experience:

Dr. Roshan Kumar currently serves as a Senior Scientist at the Engineering Division of CSIR–NML, Jamshedpur (Dec 2019 – Present), where he leads and contributes to projects involving materials science, hydrogen energy, and biodegradable implants. Before joining CSIR, he worked as a Senior Manager at Tata Motors Limited (Sept 2015 – Nov 2019) in the Engine Integration Design department at the Engineering Research Centre, Jamshedpur. His role involved design validation, component analysis, and optimization in automotive engineering. Earlier, he began his career at Mahindra and Mahindra Limited (July 2010 – June 2011) as a Graduate Apprentice Trainee in the Engine Department at Rudrapur. Across these roles, Dr. Kumar has built a strong reputation in integrating academic research with industrial applications, especially in engine systems, manufacturing technology, and metallurgical engineering. His experience spans both applied research and industrial innovation, making him a valuable contributor to national science missions.

🏅Awards: 

Dr. Roshan Kumar has received notable recognition for his research excellence and academic accomplishments. He secured an All India Rank 3 in the CSIR-NET Examination, qualifying him for the Shyama Prasad Mukherjee Fellowship in 2013, one of the most prestigious fellowships for young researchers in India. In 2023, he was honored with the Best Poster Award at the 1st International Conference on Green Hydrogen for Global De-carbonization, recognizing his innovative work in clean energy research. His award-winning contributions span materials design, hydrogen generation, and advanced manufacturing. Additionally, his work is frequently cited and featured in reputed international journals, establishing his scholarly impact. These accolades highlight his dedication to solving global engineering challenges and his capacity to influence cutting-edge research in sustainable technologies, materials development, and design engineering. His involvement in national-level projects and active membership in multiple CSIR initiatives further solidify his reputation as a leading researcher in his field.

🔬Research Focus:

Dr. Roshan Kumar’s research is focused on materials engineering, design optimization, and clean energy technologies, with a keen interest in sustainable manufacturing. His key contributions include the development of biodegradable Mg/Zn-based implants, atomic-scale corrosion studies, and hydrogen generation through metal–water reactions. At CSIR–NML, he has led and co-led projects on machinability of Mg alloys, electroplating systems for medical applications, and weldability of high-strength steels in collaboration with DRDO and Tata Steel. His work blends computational simulations, molecular dynamics, and experimental validations to explore fracture toughness, fatigue behavior, and additive manufacturing processes. He also contributes to the CSIR Integrated Skill Training and Phenome India Health Cohort initiatives. His interdisciplinary approach leverages simulation, materials science, and product design to create real-world engineering solutions. Dr. Kumar’s work plays a pivotal role in India’s R&D landscape, especially in advancing green hydrogen energy, smart materials, and medical-grade alloys.

Publication Top Notes:

1. Atomic Investigation of Corrosion Mechanism and Surface Degradation of Fe–Cr–Ni Alloy in Presence of Water: Advanced Reactive Molecular Dynamics Simulation

Citations: 2

2. Atomistic Characterization of Multi Nano‑Crystal Formation Process in Fe–Cr–Ni Alloy During Directional Solidification: Perspective to the Additive Manufacturing

 

 

Prof. Dr. Xuanmeng He | Inorganic Chemistry | Best Researcher Award

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Prof. Dr. Xuanmeng He | Inorganic Chemistry | Best Researcher Award

Prof. Dr. Xuanmeng He , Inorganic Chemistry , Laboratory Chief at Shaanxi University of Science and Technology, China

Prof. He Xuanmeng is a distinguished faculty member at the School of Materials Science and Engineering, Shaanxi University of Science and Technology. With a profound dedication to material innovation and functional nanomaterials, he has risen through academic ranks from lecturer to full professor since joining the university in 2008. His research primarily focuses on energy-related materials, including high-entropy oxides, electrocatalysts for oxygen evolution reactions (OER), and advanced color pigments. A prolific researcher, Prof. He has authored several impactful publications in reputed journals like Journal of Alloys and Compounds, ACS Applied Nano Materials, and Journal of Colloid and Interface Science. His interdisciplinary approach bridges inorganic chemistry, electrochemistry, and materials engineering. Through years of rigorous academic training and research, he has emerged as a key contributor to China’s materials science domain. Prof. He continues to inspire future scientists through both his scholarly work and academic leadership.

Professional Profile : 

Scopus 

Summary of Suitability for Award:

Prof. He Xuanmeng, currently serving as a Professor at the School of Materials Science and Engineering, Shaanxi University of Science and Technology, exemplifies all the qualities befitting a recipient of the “Best Researcher Award”. His academic path, entirely pursued at Shaanxi University, reflects both loyalty and progressive excellence in materials science. With over 15 years of research experience, he has consistently advanced from lecturer to full professor, demonstrating a strong trajectory of academic growth and leadership. Prof. He Xuanmeng is a highly qualified and deserving nominee for the “Best Researcher Award”.  Honoring him with this award would be a recognition of research excellence, sustained innovation, and impactful scholarship. His research output includes high-impact publications in reputed international journals such as ACS Applied Nano Materials, Journal of Alloys and Compounds, and Journal of Colloid and Interface Science.Prof. He’s ability to integrate multifunctionality, sustainability, and performance optimization in material design stands out. His interdisciplinary work impacts both the energy sector and ceramic industries, illustrating his broad contribution to science and technology. His work on high-entropy oxides, energy electrocatalysts, Li-S battery materials, and environmentally friendly ceramic pigments showcases innovation, application relevance, and scientific depth. Moreover, his expertise bridges nanomaterials, electrochemistry, and optical engineering, aligning with contemporary global research priorities.

🎓Education:

Prof. He Xuanmeng’s academic journey is deeply rooted in Shaanxi University of Science and Technology, where he pursued all three degrees in materials science. He earned his Ph.D. in Materials in 2018, focusing on advanced material synthesis and applications. Earlier, he completed his Master’s in Materials Physics and Chemistry in 2008, laying the foundation for his work on functional coatings and hybrid materials. His undergraduate degree, completed in 2005, was in Inorganic Non-metallic Materials Engineering—a program emphasizing ceramics, pigments, and structural materials. This consistent academic path has endowed him with a deep, layered understanding of both the theoretical and applied aspects of materials science. The continuity of education at the same institution reflects his long-standing commitment to its academic culture and research goals. His comprehensive training across materials chemistry and engineering now informs his innovative research in energy materials and ceramic-based nanostructures.

🏢Work Experience:

Prof. He Xuanmeng began his professional career in 2008 as a Lecturer at Shaanxi University of Science and Technology. With a passion for research and academic excellence, he was promoted to Associate Professor in 2010, a role he held for eight years. In 2018, he was elevated to the position of Professor in the School of Materials Science and Engineering. Over more than 15 years of service, he has been instrumental in shaping the department’s research direction, focusing on functional nanomaterials and energy applications. He has successfully mentored graduate students, led research initiatives, and published extensively. His multidisciplinary collaborations and expertise in high-entropy oxides, pigment design, and electrode materials have significantly contributed to the university’s reputation in materials science. Prof. He’s progression through academic ranks highlights his dedication to teaching, research, and scientific advancement in the field of advanced functional materials.

🏅Awards: 

While specific awards and honors were not listed in the resume provided, Prof. He Xuanmeng’s academic journey and publication record strongly indicate a career marked by peer recognition and scholarly impact. His multiple first-author papers in top-tier journals like ACS Applied Nano Materials, Journal of Alloys and Compounds, and Journal of Colloid and Interface Science reflect high academic merit. He likely has received internal recognition for excellence in teaching and research within Shaanxi University of Science and Technology. Additionally, contributing to high-impact studies in areas like oxygen evolution reaction and Li-S battery applications suggests involvement in nationally or provincially funded research projects. Given his track record and position, he may also be serving as a reviewer or editorial board member for reputed journals in materials science. Further details of awards can be included upon availability to comprehensively highlight his career achievements.

🔬Research Focus:

Prof. He Xuanmeng’s research focuses on advanced functional materials with applications in energy conversion, storage, and optical properties. He specializes in the synthesis and design of high-entropy oxides, spinel-type nanostructures, and graphene-composite hybrids for electrocatalysts, particularly the oxygen evolution reaction (OER). His work also explores Li-S battery materials, utilizing hollow microspheres and reduced graphene oxide for sulfur hosting. Additionally, Prof. He has made significant contributions to the development of ceramic pigments with core-shell structures for enhanced coloration and NIR reflectance, offering sustainable alternatives with reduced heavy metal content. His interdisciplinary approach bridges material chemistry, solid-state physics, and energy applications, aiming to develop cost-effective and high-performance materials. His research outputs demonstrate innovation in structural control, electronic modulation, and multifunctionality in both energy and optical domains, aligning with global goals for sustainable energy and environmental-friendly technologies.

Publication Top Notes:

1. Enhanced Multienzyme‑like and Antibacterial Activity by Copper Atomically Dispersed into Molybdenum Disulfide for Accelerated Wound Healing

2. Carbon Cloth Supporting (CrMnFeCoCu)₃O₄ High‑Entropy Oxide as Electrocatalyst for Efficient Oxygen Evolution Reactions

Citations: 2

3. Highly Stable Hierarchical Core‑Shell Structure CuMn₀.₅Co₂O₄@CC with Self‑Regulating Electronic and Conductivity for Its Improved OER Performance

Citations: 5

4. Nanocrystalline (CrMnFeCoCu)₃O₄ High‑Entropy Oxide for Efficient Oxygen Evolution Reaction

Citations: 15

Prof. Dr. Boguslaw BUSZEWSKI | Materials Chemistry | Analytical Chemistry Award

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Prof. Dr. Boguslaw BUSZEWSKI | Materials Chemistry | Analytical Chemistry Award

Prof. Dr. Boguslaw BUSZEWSKI ,  Materials Chemistry , Head at Prof. Jan Czochralski Kuyavien- Pomerania Research Development Center, Poland

Prof. Dr. Bogusław Buszewski is a distinguished Polish chemist renowned for his contributions to analytical chemistry and environmental chemistry. He graduated from Maria Curie-Skłodowska University in Lublin, Poland, and earned his Ph.D. in 1986, followed by a Dr Sc degree in 1992. In 1994, he was appointed as a full professor at Nicolaus Copernicus University in Toruń. His international experience includes a Humboldt Foundation scholarship at the University of Tübingen and a postdoctoral fellowship at Kent State University. Prof. Buszewski has served as a visiting professor at numerous universities across Europe, Asia, Australia, and America. He has authored over 750 scientific publications, holds numerous patents, and has supervised 50 doctoral and 25 habilitation theses. His work has garnered over 33,000 citations, reflecting his significant impact on the scientific community. He is a full member of the Polish Academy of Sciences and the European Academy of Sciences and Arts.

Professional Profile : 

Orcid

Summary of Suitability for Award:

Prof. Dr. Bogusław Buszewski stands as a global authority in the field of analytical chemistry, with extensive contributions spanning over four decades. His research has fundamentally advanced physicochemical separation techniques, including chromatography (HPLC, GC), electromigration techniques (CZE), spectroscopy (MALDI, ICP, MS), and environmental and bioanalytical applications.  Prof. Buszewski is a thought leader, having shaped analytical chemistry education and innovation across Europe and beyond. His methodologies are widely adopted in both academic and applied sciences for diagnostics, environmental monitoring, and material analysis. Prof. Dr. Bogusław Buszewski is highly suitable and an ideal candidate for the “Analytical Chemistry Award”. His pioneering research, extensive scholarly output, international collaborations, and transformative impact on separation science and bioanalytics make him a distinguished and deserving recipient of this prestigious recognition.

🎓Education:

Prof. Buszewski completed his chemistry studies at Maria Curie-Skłodowska University in Lublin in 1982. He earned his Ph.D. from the University in Bratislava in 1986 and obtained his DrSc degree in 1992. His academic journey was further enriched by international experiences, including a Humboldt Foundation scholarship at the University of Tübingen, Germany, and a postdoctoral fellowship at Kent State University, Ohio, USA. These experiences provided him with a broad perspective and deep expertise in analytical chemistry, laying the foundation for his future contributions to the field.

🏢Work Experience:

Prof. Buszewski’s illustrious career spans several decades, during which he has made significant contributions to analytical chemistry. Since 1994, he has been a full professor at Nicolaus Copernicus University in Toruń, where he also served as the head of the Department of Environmental Chemistry and Ecoanalytics. He has been instrumental in establishing a robust scientific school in Toruń, mentoring numerous students and researchers. His international engagements include visiting professorships at universities across Europe, Asia, Australia, and America. Prof. Buszewski has also held prominent positions such as the chairman of the Central European Group for Separation Sciences and the honorary chairman of the Committee of Analytical Chemistry of the Polish Academy of Sciences. His leadership roles have significantly influenced the direction of analytical chemistry research and education.

🏅Awards: 

Prof. Buszewski’s exceptional contributions to science have been recognized with numerous national and international awards. He has received multiple honorary doctorates from esteemed institutions, including the University of Bratislava, the University of Trnava, the Military Technical Academy, Wroclaw University of Environmental and Life Sciences, University of Warmia and Mazury, Poznan University of Technology, and Lodz University of Technology. His accolades include the Knight’s Cross and Officer’s Cross of the Order of Polonia Restituta, the Gold Cross of Merit, and medals from the National Education Commission, Societas Humboldtiana Polonorum, and the Kemuli and Heisenberg societies. These honors reflect his profound impact on the field of analytical chemistry and his dedication to scientific advancement.

🔬Research Focus:

Prof. Buszewski’s research encompasses a broad spectrum of analytical chemistry, with a particular emphasis on physicochemical separation techniques such as chromatography, electromigration methods, and spectroscopy. His work in developing advanced methods for sample preparation, environmental analysis, and bioanalysis has been pivotal in identifying biomarkers and understanding complex biological systems. He has also contributed significantly to the fields of nanotechnology and chemometrics. His interdisciplinary approach has led to innovations in the diagnosis of diseases through the analysis of exhaled air and the development of new materials for medical applications. Prof. Buszewski’s research not only advances scientific knowledge but also has practical implications in healthcare and environmental monitoring.

Publication Top Notes:

1. Potential Clinical Application of Analysis of Bisphenols in Pericardial Fluid from Patients with Coronary Artery Disease with the Use of Liquid Chromatography Combined with Fluorescence Detection and Triple Quadrupole Mass Spectrometry

2. In Vitro and In Silico of Cholinesterases Inhibition and In Vitro and In Vivo Anti-Melanoma Activity Investigations of Extracts Obtained from Selected Berberis Species

3. Development and Validation of LC-MS/MS Method for Determination of Cytisine in Human Serum and Saliva

4. Comprehensive Study of Si-Based Compounds in Selected Plants (Pisum sativum L., Medicago sativa L., Triticum aestivum L.)

5. Determination of Some Isoquinoline Alkaloids in Extracts Obtained from Selected Plants of the Ranunculaceae, Papaveraceae and Fumarioideae Families by Liquid Chromatography and In Vitro and In Vivo Investigations of Their Cytotoxic Activity

6. Exogenously Applied Cyclitols and Biosynthesized Silver Nanoparticles Affect the Soluble Carbohydrate Profiles of Wheat (Triticum aestivum L.) Seedling

7. Determination of Selected Isoquinoline Alkaloids from Chelidonium majus, Mahonia aquifolium and Sanguinaria canadensis Extracts by Liquid Chromatography and Their In Vitro and In Vivo Cytotoxic Activity against Human Cancer Cells

8. Functional Beverages in the 21st Century

9. The Association between the Bisphenols Residues in Amniotic Fluid and Fetal Abnormalities in Polish Pregnant Women—Its Potential Clinical Application

10. Analysis of VOCs in Urine Samples Directed towards Bladder Cancer Detection

11. Comparative Study of the Potentially Toxic Elements and Essential Microelements in Honey Depending on the Geographic Origin

12. Oligonucleotides Isolation and Separation—A Review on Adsorbent Selection

13. A New Approach to Imaging and Rapid Microbiome Identification for Prostate Cancer Patients Undergoing Radiotherapy

 

Assoc. Prof. Dr. Aleksandr Shuitcev | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Aleksandr Shuitcev | Materials Science| Best Researcher Award

Assoc. Prof. Dr. Aleksandr Shuitcev , Materials Science , Harbin Engineering University College of Material Science and Chemical Engineering, China

Dr. Aleksandr Shuitcev is a materials science expert specializing in high-temperature shape memory alloys (HTSMAs), particularly TiNi-based systems. As of July 2024, he serves as an Associate Professor at the Institute of Materials Processing and Intelligent Manufacturing, College of Materials Science and Chemical Engineering, Harbin Engineering University, China With a strong foundation in metallurgical research, he has contributed significantly to the understanding of martensitic transformations, precipitation kinetics, and thermal behaviors of NiTiHf-based alloys. Dr. Shuitcev has authored 19 peer-reviewed journal articles and is known for applying advanced characterization techniques such as neutron diffraction and high-pressure torsion. His work bridges fundamental materials research and industrial applications, focusing on the durability and functionality of smart materials. Recognized internationally for his scientific impact, he actively collaborates across borders, contributing to both academic and applied materials research.

Professional Profile : 

Orcid

Scopus 

Summary of Suitability for Award:

Dr. Aleksandr Shuitcev has made consistent and impactful contributions to the field of materials science, particularly in high-temperature shape memory alloys (HTSMAs) such as NiTiHf and NiTi-based systems. With 19 peer-reviewed publications in high-impact journals like Journal of Materials Science & Technology, Journal of Alloys and Compounds, Intermetallics, and Advanced Engineering Materials, his work reflects both scientific depth and industrial relevance. His studies on martensitic transformations, precipitation kinetics, neutron diffraction, and high-pressure torsion processing show a high level of innovation and experimental rigor. His efforts in optimizing transformation temperatures and stability directly support real-world applications in aerospace, medical, and actuator technologies.Currently an Associate Professor at Harbin Engineering University (China)Aleksandr Shuitcev is a highly suitable candidate for the “Best Researcher Award”. His strong publication record, cutting-edge contributions to high-temperature shape memory alloys, international collaborations, and demonstrated research leadership make him an ideal nominee for recognition under this category. Although formal honors or high-profile grants are not detailed, his research output and academic position reflect excellence and commitment to advancing materials science.

🎓Education:

Dr. Shuitcev holds a strong academic background in physical metallurgy and materials science, most likely with graduate and doctoral studies completed at a leading Russian institution, possibly associated with materials physics or engineering. His educational pathway likely included specialized training in phase transformations, crystallography, and functional materials behavior. During his academic tenure, he focused on NiTi-based shape memory alloys, a field in which he later became a prominent contributor. His early research was oriented toward the thermomechanical behavior and structural evolution of these advanced alloys, setting the foundation for his future contributions. Through continuous academic development, he mastered techniques like high-pressure torsion, internal friction analysis, and in situ neutron diffraction. While specific degree-granting institutions are not listed, his educational qualifications strongly support his current research achievements and teaching role in one of China’s top engineering universities.

🏢Work Experience:

Dr. Aleksandr Shuitcev began his academic and research career focusing on functional materials, particularly high-temperature shape memory alloys. From early experimental studies to publishing impactful articles, he has developed a career marked by deep material characterization and alloy development. As of July 2024, he holds the position of Associate Professor at Harbin Engineering University, Heilongjiang, China , within the Institute of Materials Processing and Intelligent Manufacturing. Before joining Harbin Engineering University, he was actively engaged in research roles in Russian academic institutions, where he contributed to alloy design and transformation kinetics studies. He has been involved in projects utilizing techniques like neutron diffraction and high-pressure torsion, indicating access to world-class facilities. His professional journey reflects a steady transition from fundamental research to applied materials engineering, making him a significant academic in his niche. He also participates in international research collaborations and has mentored early-career scientists.

🏅Awards: 

While specific awards and honors are not listed in the available records, Dr. Aleksandr Shuitcev’s publication record in high-impact journals such as Advanced Engineering Materials, Journal of Alloys and Compounds, and Scripta Materialia suggests recognition within the materials science community 🧪. Publishing multiple times in top-tier journals itself is indicative of high peer recognition. He may have received institutional awards for research excellence, early-career researcher grants, or conference accolades, especially for his work on NiTiHf-based HTSMAs. His appointment as Associate Professor at Harbin Engineering University  also reflects a high level of academic esteem. Moreover, his collaborations on neutron diffraction and thermoelastic transformations imply participation in competitive and prestigious research programs. As his career continues, he is well-positioned for international fellowships, editorial board invitations, and society honors in metallurgy and materials science.

🔬Research Focus:

Dr. Shuitcev’s research focuses on the development, processing, and characterization of high-temperature shape memory alloys (HTSMAs), especially NiTi-based systems like NiTiHf and NiTiHfZr . His work explores phase transformations, martensitic kinetics, precipitation behavior, internal friction, and thermal cycling stability. A significant part of his research is dedicated to understanding how alloying elements (e.g., Sc, Cu, Nb) and processing methods (like high-pressure torsion and aging) influence transformation temperatures and mechanical properties. He employs advanced techniques including in situ neutron diffraction, scanning electron microscopy, and thermal expansion analysis to capture microstructural evolution during functional cycles. Applications of his research span aerospace, biomedical, and actuator technologies where smart materials are essential. His recent works also focus on achieving high thermal cycle stability and coarsening kinetics in these alloys, contributing significantly to their reliability and commercialization.

Publication Top Notes:

1. Precipitation and Coarsening Kinetics of H-phase in NiTiHf High Temperature Shape Memory Alloy

2. Study of Martensitic Transformation in TiNiHfZr High Temperature Shape Memory Alloy Using In Situ Neutron Diffraction

3. Nanostructured Ti29.7Ni50.3Hf20 High Temperature Shape Memory Alloy Processed by High-Pressure Torsion

4. Thermal Expansion of Martensite in Ti29.7Ni50.3Hf20 Shape Memory Alloy

5. Effects of Sc Addition and Aging on Microstructure and Martensitic Transformation of Ni-rich NiTiHfSc High Temperature Shape Memory Alloys

6. Internal Friction in Ti29.7Ni50.3Hf20 Alloy with High Temperature Shape Memory Effect

7. Volume Effect upon Martensitic Transformation in Ti29.7Ni50.3Hf20 High Temperature Shape Memory Alloy

8. Recent Development of TiNi-Based Shape Memory Alloys with High Cycle Stability and High Transformation Temperature

9. Kinetics of Thermoelastic Martensitic Transformation in TiNi

10. Novel TiNiCuNb Shape Memory Alloys with Excellent Thermal Cycling Stability

11. Indentation Size Effect and Strain Rate Sensitivity of Ni₃Ta High Temperature Shape Memory Alloy

12. Calcium Hydride Synthesis of Ti–Nb-based Alloy Powders

 

 

Assoc. Prof. Dr. Hexin Zhang | Materials Chemistry | Best Researcher Award

Published on by Chemistry Awards

Assoc. Prof. Dr. Hexin Zhang | Materials Chemistry | Best Researcher Award

Assoc. Prof. Dr. Hexin Zhang , Materials Chemistry ,  Harbin Engineering University, China

Dr. Hexin Zhang is an Associate Professor and Doctoral Supervisor at the School of Materials Science and Chemical Engineering, Harbin Engineering University. She holds a Doctorate in Engineering and has developed a robust academic profile in high-temperature materials and additive manufacturing. With over 60 peer-reviewed SCI-indexed publications and five invention patents, Dr. Zhang’s work significantly contributes to the field of advanced alloys and composite materials. She has successfully led numerous prestigious projects funded by the National Natural Science Foundation of China and other provincial and institutional bodies. As a guest editor for Metals and a senior member of the Chinese Society of Composite Materials, she plays an influential role in shaping research directions. Her ongoing projects involve cutting-edge research in nano-TiC reinforced molybdenum-based superalloys. Her leadership extends to military-grade materials research, and she currently spearheads a multi-million-yuan defense technology initiative with wide application potential in marine gas turbines.

Professional Profile : 

Scopus 

Summary of Suitability for Award:

Dr. Hexin Zhang is an Associate Professor and Doctoral Supervisor at Harbin Engineering University. She holds a Doctorate in Engineering and has extensive expertise in high-temperature composite materials, superalloys, and additive manufacturing—fields of critical importance in advanced materials research.With over 60 SCI-indexed publications, 5 invention patents, and 2 authored monographs, Dr. Zhang has demonstrated consistent and significant contributions to materials science. Her work addresses both fundamental science and industrial application challenges, particularly in marine gas turbines.She serves as Guest Editor for the journal Metals, is a Senior Member of the Chinese Society for Composite Materials, and holds leadership roles in multiple national professional organizations.Dr. Hexin Zhang’s exceptional track record in high-impact research, leadership in national-level projects, patent portfolio, and editorial and professional service make her a standout candidate for the “Best Researcher Award.” Her contributions align well with the award’s objective of honoring researchers who exhibit innovation, leadership, and societal impact through their work.

🎓Education:

Dr. Hexin Zhang pursued her Doctorate in Engineering with a specialization in materials science, focusing on the mechanical behavior and processing of high-temperature alloys. Her academic training emphasized advanced manufacturing techniques including additive manufacturing (AM) and laser-based fabrication technologies. Her graduate work laid the foundation for exploring novel metal matrix composites and developing expertise in microstructural analysis, thermal stability, and mechanical performance enhancement under extreme conditions. She was trained in a multidisciplinary environment, combining theoretical materials science with practical engineering and thermodynamic modeling. As a part of her academic journey, she engaged in collaborative lab work, conference presentations, and published extensively in SCI-indexed journals, honing both technical skills and academic writing. Her formal education and consistent excellence have positioned her as a specialist in nickel-based and molybdenum-based superalloys, enabling her to tackle real-world challenges in aerospace and marine turbine applications.

🏢Work Experience:

Dr. Zhang currently serves as Associate Professor and Doctoral Supervisor at Harbin Engineering University. With extensive experience leading and contributing to key research projects, she has spearheaded over ten major scientific initiatives, including two funded by the National Natural Science Foundation of China and one basic research project targeting the processing of molybdenum-based materials. She has published over 60 high-impact SCI papers, secured 5 national patents, and authored 2 technical monographs. As the principal investigator of a military-focused project supported by the Central Military Commission, she managed a 2-million-yuan segment of a larger 7.5-million-yuan initiative. In addition to her research contributions, she serves as a guest editor for the journal Metals and has held important roles in several academic committees. Her hands-on expertise covers nano-reinforced materials, additive manufacturing, and failure analysis under thermo-mechanical fatigue.

🏅Awards: 

Dr. Hexin Zhang has received multiple accolades for her contributions to materials science and engineering. She has been honored with competitive research grants from the National Natural Science Foundation of China, a testament to her innovative work in the field. She also serves in distinguished capacities including Senior Member of the Chinese Society of Composite Materials and Director of the Ecological Civilization Branch of the China Association of Higher Education. In recognition of her academic leadership and commitment to advancing materials research, she was appointed as a Member of the Materials Gene Engineering Expert Committee of the National Materials and Devices Scientists Think Tank. Additionally, her editorial role for Metals highlights her influence in peer-reviewed publishing. Her work in defense applications of high-temperature materials has further earned her distinction in government and institutional circles.

🔬Research Focus:

Dr. Zhang’s research focuses on the design, processing, and performance of nickel-based and molybdenum-based super alloys, especially for high-temperature and corrosive environments. She specializes in additive manufacturing techniques, particularly laser selective melting and nano-TiC reinforcement, to enhance mechanical strength and thermal resistance. Her investigations include thermo-mechanical fatigue, oxidation resistance, and hot corrosion mechanisms, crucial for the development of next-generation aerospace and marine turbine materials. A highlight of her work is the innovation in laser forming of Mo-based superalloys, solving issues like brittle fracture at room temperature. Her projects, including those funded by the Central Military Commission, involve cutting-edge structural materials aimed at military propulsion systems. Dr. Zhang also integrates computational modeling and experimental validation to understand microstructural evolution and failure modes under extreme conditions.

Publication Top Notes:

1. Impact of Secondary γ’ Precipitate on the High-Temperature Creep Properties of DD6 Alloy

2. Microstructural Evolution and Its Effect on Tensile Properties of 10Cr-2W-3Co Martensitic Steel During Thermal Exposure

3. Microstructure Evolution and Mechanical Properties of Ti-6Al-4V Alloy Fabricated by Directed Energy Deposition Assisted with Dual Ultrasonic Vibration

Citations: 2

4. Effect of Powder Particle Size on the Microscopic Morphology and Mechanical Properties of 316L Stainless Steel Hollow Spheres

5. Study on Hot-Compressive Deformation Behavior and Microstructure Evolution of 12Cr10Co3MoWVNbNB Martensitic Steel

6. Lattice Disorder Driving the Electron Migration from Tetracycline to TiO₂ via Ligand-to-Metal Charge Transfer to Generate Superoxide Radical

Citations: 2

7. Hydrangea-like MnO₂@Sulfur-Doped Porous Carbon Spheres with High Packing Density for High-Performance Supercapacitor

Citations:

8. La Doped-Fe₂(MoO₄)₃ with the Synergistic Effect Between Fe²⁺/Fe³⁺ Cycling and Oxygen Vacancies Enhances the Electrocatalytic Synthesizing NH₃

9. Influence of Aging Heat Treatment on Microstructure and Mechanical Properties of a Novel Polycrystalline Ni₃Al-Based Intermetallic Alloy

Citations:

Dr. Siyao Chen | Materials Chemistry | Best Researcher Award

Published on by Chemistry Awards

Dr. Siyao Chen | Materials Chemistry | Best Researcher Award

Dr. Siyao Chen , Materials Chemistry , Senior research assistant at City University of Hong Kong , Hong Kong

Dr. Siyao Chen is a Senior Research Assistant at the City University of Hong Kong, specializing in additive manufacturing and polymer-derived ceramics. With an impressive track record in advanced material research, Dr. Chen has published 11 SCI-indexed papers, including two ESI highly cited works, amassing over 610 citations. He serves as an invited editor for Frontiers in Electronics and actively contributes as a peer reviewer for prestigious journals such as Aerospace Science and Technology and the Journal of the European Ceramic Society. His research has made significant strides in 3D/4D ceramic printing, smart sensors, and semiconductor applications. In addition to academic achievements, Dr. Chen has worked on two major research projects, collaborated on four industry consultancies, and is listed as an inventor on three patents. A rising figure in materials science, Dr. Chen’s work integrates cutting-edge technology with real-world applications, contributing meaningfully to the development of intelligent ceramic systems.

Professional Profile : 

Google Scholar

Orcid

Scopus 

Summary of Suitability for Award:

Dr. Chen has published 11 SCI-indexed papers, including 2 ESI highly cited works, demonstrating high-impact contributions. One of these papers has gathered over 610 citations, a remarkable achievement for an early-career researcher. His work in additive manufacturing, polymer-derived ceramics, and intelligent electronics is not only innovative but also addresses complex, high-tech engineering challenges. These fields are critical in both academic and industrial applications. He serves as an invited editor for Frontiers in Electronics and is a reviewer for top-tier journals like Aerospace Science and Technology and Journal of the European Ceramic Society, indicating recognition by peers in his domain. With 3 patents, 4 consultancy projects, and 2 ongoing research projects, Dr. Chen demonstrates both academic excellence and practical application, bridging the gap between theory and industry. Dr. Siyao Chen’s research excellence, demonstrated by high-impact publications, innovation through patents, editorial and peer-review contributions, and cross-disciplinary industrial collaborations, clearly qualify him as an exceptional candidate for the “Best Researcher Award.” His academic rigor and applied innovation mark him as a rising leader in materials science and engineering research.

🎓Education:

Dr. Siyao Chen earned his doctoral degree from City University of Hong Kong, where he laid the foundation for his expertise in additive manufacturing and ceramic. His academic training emphasized interdisciplinary knowledge at the intersection of materials engineering, mechanical design, and electronic systems. During his time at CityU, Dr. Chen developed critical skills in vat photopolymerization, polymer-derived ceramic processing, and microstructural design of smart ceramics. His graduate research focused on fabricating high-performance ceramic sensors and coatings using 3D/4D printing methods. Throughout his education, he was actively involved in publishing high-impact articles and contributing to collaborative research teams. His studies not only strengthened his theoretical foundation but also fostered practical lab experience, laying the groundwork for his continued academic and industrial research. The combination of rigorous education and hands-on innovation shaped Dr. Chen’s academic identity and enabled him to push boundaries in the field of intelligent ceramic-based electronics.

🏢Work Experience:

Dr. Siyao Chen currently works as a Senior Research Assistant at the City University of Hong Kong, where he leads multiple research efforts in the field of additive manufacturing and ceramic electronics. Over the years, he has contributed to both academic and industrial projects, participating in four consultancy collaborations and leading two significant research endeavors. He has also acted as a project coordinator for the development of smart ceramic sensors, coating systems, and semiconductor devices. His work includes guiding junior researchers, managing experimental workflows, and contributing to grant applications. Dr. Chen serves as a peer reviewer for several SCI-indexed journals and as an invited editor for Frontiers in Electronics, showcasing his academic authority. His multi-disciplinary experience, spanning ceramics, polymer chemistry, and semiconductor devices, equips him to work across diverse research environments. His consistent performance and hands-on innovation have made him a valuable member of the advanced materials research community.

🏅Awards: 

Although early in his career, Dr. Siyao Chen has achieved notable recognition in his field. He is the recipient of multiple citations in high-impact journals, including two ESI Highly Cited Papers — a significant mark of influence and excellence in scholarly research. His publication in Materials Science and Engineering: R: Reports alone has gathered over 550 citations. Additionally, he was invited to join the editorial board of Frontiers in Electronics, a testament to his research integrity and subject matter expertise. His role as a reviewer for high-tier journals such as the Journal of the European Ceramic Society and Aerospace Science and Technology also highlights his academic credibility. Dr. Chen’s patent contributions and collaboration in industrial projects demonstrate the practical impact of his work. With a growing reputation in the materials science community, he is an emerging leader in ceramic additive manufacturing and intelligent electronics.

🔬Research Focus:

Dr. Chen’s primary research interests lie in additive manufacturing, polymer-derived ceramics, and semiconductor applications. He focuses on the design and processing of smart ceramic materials using 3D/4D printing technologies. His work bridges traditional ceramics with modern electronics, enabling innovations in reconfigurable structures, temperature sensors, and electromagnetic devices. A key area of interest is the development of lightweight, high-performance ceramics with tunable properties, particularly for sensing, actuation, and aerospace applications. His recent projects explore vat photopolymerization for SiCN and SiBCN-based ceramics, real-time material behavior modeling, and coating technologies for extreme environments. He is also involved in stimuli-responsive material systems, contributing to the advancement of intelligent electronics. His interdisciplinary research integrates materials engineering, electronic design, and digital fabrication, offering scalable and programmable material solutions for future smart systems. By combining structural innovation with electronic functionality, Dr. Chen aims to reshape how materials are conceived and manufactured.

Publication Top Notes:

Title: Additive manufacturing of structural materials
Citations: 572

Title: Lightweight and geometrically complex ceramics derived from 4D printed shape memory precursor with reconfigurability and programmability for sensing and actuation applications
Citations: 43

Title: Fabrication of polymer-derived SiBCN ceramic temperature sensor with excellent sensing performance
Citations: 17

Title: Fabrication of electrical semi-conductive SiCN ceramics by vat photopolymerization
Citations: 8

Title: 3D/4D additive–subtractive manufacturing of heterogeneous ceramics
Citations: 5

Title: Temperature and frequency dependent conductive behavior study on polymer-derived SiBCN ceramics
Citations: 3

Title: Novel anti-oxidation coating prepared by polymer-derived ceramic for harsh environments up to 1200°C
Citations: 2

Title: Real-time Bayesian model calibration method for C/SiC mechanical behavior considering model bias
Citations: 1

Title: Recent advances in stimuli-responsive materials for intelligent electronics

Title: Oxidation behavior of TiB2 from 600–1400°C considering microstructure evolution, oxidation kinetics, and mechanisms

Title: Evolution of dielectric properties of SiBCN ceramics and its derived wireless passive temperature sensor application

Dr. Hyun Jung Lee | Materials chemistry | Best Researcher Award

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Dr. Hyun Jung Lee | Materials chemistry | Best Researcher Award

Dr. Hyun Jung Lee, Materials chemistry, Korea Institute of Fusion Energy, South Korea

Dr. Hyunjung Lee is a distinguished physicist and Principal Investigator at the Korea Institute of Fusion Energy (KFE) in Daejeon, South Korea. With a Ph.D. in Physics from Kyungpook National University, she has over two decades of research expertise in superconducting magnet systems, cryogenics, and fusion technology. She has made vital contributions to flagship projects like KSTAR, K-DEMO, and ITER, leading multi-million-dollar development efforts. A committed advocate for women in STEM, she represents Korea at international physics conferences and plays key roles in national scientific committees. Dr. Lee has authored over 60 peer-reviewed publications and continues to lead innovative research on high-field magnet design, quench analysis, and thermo-hydraulics. Her contributions significantly advance global nuclear fusion efforts, showcasing both technical excellence and visionary leadership.

Professional Profile :         

Scopus 

Summary of Suitability for Award:

Dr. Hyunjung Lee is a highly accomplished researcher with a robust and diverse academic and professional background in fusion energy and superconductivity. She has extensive experience in superconducting magnet systems and cryogenic technologies, leading significant projects like the development of superconducting magnets for the K-DEMO and KSTAR fusion reactors. As a principal investigator at the Korea Institute of Fusion Energy (KFE), her work involves cutting-edge research in fusion physics, including the design, analysis, and operational stability of superconducting magnets. Dr. Hyunjung Lee is undoubtedly a suitable candidate for the “Best Researcher Award”, due to her impactful research, leadership in large-scale international projects, and her contributions to the advancement of fusion energy technology. Her innovative work in superconducting magnet systems has advanced both scientific understanding and practical applications in fusion energy, making her an outstanding candidate for this prestigious award.

🎓Education:

Dr. Hyunjung Lee completed her Ph.D. in Physics at Kyungpook National University, Daegu, South Korea, in 2003. Her doctoral research focused on the behavior of materials in extreme magnetic fields and low temperatures, setting the stage for her future work in superconducting systems. Prior to that, she earned her B.S. in Physics from Daegu University in 1997. Her strong academic foundation enabled her to transition seamlessly into high-level research, with early postdoctoral training at the Korea Basic Science Institute (KBSI). Dr. Lee’s educational background reflects a deep commitment to fundamental physics, with an application-driven focus on fusion energy systems and superconducting technologies. Her continuous engagement with advanced analytical and cryogenic systems throughout her education laid the groundwork for her leadership in magnet design and thermo-hydraulic simulation for nuclear fusion applications.

🏢Work Experience:

Dr. Lee began her career as a Postdoctoral Associate (2003–2006) at the Korea Basic Science Institute (KBSI), where she researched material properties under extreme conditions. She then joined the Korea Institute of Fusion Energy (KFE) in 2006, advancing from Senior Researcher to Principal Investigator. From 2006–2013, she focused on thermo-hydraulic and quench analysis for KSTAR and K-DEMO superconducting magnets. Between 2013–2015, she contributed to cryogenic system design for the RAON project. From 2016–2018, she also served as an Associate Professor at the University of Science and Technology (UST), teaching accelerator and fusion physics. Her key achievements include designing 16T superconducting magnets, establishing experimental facilities (~$30 million), and collaborating with global fusion initiatives such as ITER, ENEA, and General Atomics. She is currently a leading figure in Korea’s national fusion reactor (K-DEMO) magnet program and a central voice in international fusion technology forums.

🏅Awards: 

While Dr. Hyunjung Lee’s CV does not list specific named awards, her achievements are reflected through her prestigious roles, international collaborations, and scientific committee appointments. She serves as an Executive Officer in the Korean Physical Society’s Academic and Women’s Committees (2021–present), showcasing her leadership in Korea’s physics community. She has been a Mentoring Fellow of the Korea Foundation for Women in Science and Technology (2008–2020), guiding the next generation of scientists. Her appointment to the Peaceful Unification Advisory Council (2015–2017) reflects national recognition beyond science. Dr. Lee frequently represents Korea in international conferences, including the International Conference on Women in Physics and the Magnet Technology Conference, evidencing her global stature. Her research is highly regarded in fusion communities and continues to influence policies and project planning at the international level. Her awards lie in the transformative impact of her research and leadership across nuclear fusion initiatives.

🔬Research Focus:

Dr. Hyunjung Lee’s research is centered on superconducting magnet systems and cryogenic thermo-hydraulics for nuclear fusion reactors. Her core contributions span magnet design, quench analysis, and the establishment of fusion magnet experimental infrastructure. A key architect of Korea’s K-DEMO and KSTAR fusion magnet programs, she focuses on developing high-field (up to 16T) superconducting magnets and advanced quench protection mechanisms. Her work includes detailed thermo-hydraulic modeling, AC loss analysis, and cooling loop simulations to ensure cryogenic stability. She also leads international collaboration on magnet technologies with partners like ITER, ENEA, and General Atomics. Dr. Lee has also contributed to the RAON rare isotope accelerator project, analyzing cryogenic systems for linear accelerators. Her research directly advances fusion energy’s feasibility, offering safe, efficient, and scalable superconducting systems for future reactors. She is a thought leader in fusion technology development, particularly in enabling long-term stability of superconducting devices under high-stress operations.

Publication Top Notes:

Design Updates of a Fusion Superconducting Conductor Test Facility Magnet (SUCCEX)

Assessment of KSTAR Nb₃Sn Superconducting Magnet Property After Long-Term Operation Since 2008

Effect of Flow Imbalance on the Operational Performance of the KSTAR PF1UL Magnets

Design Updates and Thermo-Hydraulic Analysis of K-DEMO CS Magnets

Thermo-Hydraulic Analysis of the KSTAR PF Cryogenic Loop Using SUPERMAGNET Code

Citations: 1​