Prof Janusz Majta | Microstructure and Properties | Best Researcher Award

Prof. Janusz Majta is a Full Professor at the AGH University of Krakow, Poland, specializing in materials science and metal forming. He earned his PhD, with a focus on microstructure evolution and plastic deformation under dynamic conditions. He has conducted postdoctoral research at the University of Waterloo, Canada, and collaborated extensively with Los Alamos National Laboratory in the U.S. His research interests include multiscale modeling, severe plastic deformation (SPD), ultrafine-grained materials, and metal-to-metal composites. Prof. Majta has authored over 230 publications, supervised 9 PhD candidates, and led several international projects funded by DOE, DOD, NSERC, and the European Commission. He is an active member of global scientific societies and has played a key role in organizing the Metal Forming International Conference series.

Prof Janusz Majta, AGH University of Krakow, Poland

Profile

ORCID

🎓 Education

Prof. Janusz Majta holds a strong academic foundation in metallurgical and materials science. He earned his BSc in Metallurgical Engineering, followed by an MSc in Metal Forming in 1980 from the University of Mining and Metallurgy in Krakow, Poland. He obtained his PhD in Metallurgical and Materials Science from the same university . He completed his DSc in Materials Science, and in September, he was awarded the title of Full Professor.

💼 Experience

Prof. Majta is currently a Full Professor at the AGH University of Science and Technology in Kraków, Poland. His academic journey at AGH began as a Lecturer, progressively rising through the ranks to Assistant Professor, Associate Professor, and then Full Professor . Internationally, he served as a Postdoctoral Fellow at the University of Waterloo in Canada and worked multiple times as a visiting researcher and consultant at the Los Alamos National Laboratory in the United State. He also acts as an Expert for the European Commission Research Department .

🛠️ Contributions

Prof. Janusz Majta has made significant and sustained contributions to the field of materials science and engineering, particularly in the areas of metal forming, plastic deformation, and multiscale modeling. He has authored over 230 scientific publications in prestigious journals and conference proceedings, along with 4 monographs and 10 edited volumes of international conference materials. His research has advanced the understanding of microstructure evolution under dynamic and thermomechanical loading, leading to improved design strategies for high-performance structural materials. Prof. Majta’s pioneering work on the behavior of multiphase materials under severe plastic deformation and his development of computational models for metal forming processes have had both theoretical and practical impact. Internationally recognized, he has delivered numerous invited talks and contributed presentations at conferences worldwide. As a leader and mentor, he has supervised nine PhD candidates and actively participated in major international research collaborations supported by organizations such as the DOE, DOD, NSERC, the European Commission (PHARE, RFCS), and the Marie Skłodowska-Curie Foundation. Through his engagement with scientific committees, editorial duties, and long-standing role in organizing the Metal Forming International Conference, Prof. Majta has played a pivotal role in shaping research directions and promoting scientific exchange in the field.

📡 Research Projects

Prof. Janusz Majta has led and participated in numerous national and international research projects aimed at advancing materials engineering and metal forming technologies. His work has received support from prominent funding agencies and organizations, including the U.S. Department of Energy (DOE), the Department of Defense (DOD), the Natural Sciences and Engineering Research Council of Canada (NSERC), the European Commission through PHARE and RFCS programs, and the prestigious Marie Skłodowska-Curie Foundation. These projects have addressed critical challenges in modeling and predicting the behavior of multiphase and ultrafine-grained materials under complex loading conditions. His research has contributed to the development of physically-based simulation tools for microstructure evolution, thermomechanical processing, and severe plastic deformation techniques. Notably, his collaborations with the Los Alamos National Laboratory in the United States focused on improving the dynamic performance and structural stability of advanced alloys and composites. Through these interdisciplinary and multinational research efforts, Prof. Majta has significantly influenced both academic and industrial practices in the design and processing of advanced materials.

🔬 Research Focus

Prof. Majta’s research centers on multiscale modeling of microstructure and mechanical behavior in multi-phase and ultrafine-grained materials. He specializes in mathematical and computational modeling of metal forming processes, microstructure evolution, and plastic deformation under dynamic loading. His work emphasizes physically-based design of structural materials with superior properties, including SPD (Severe Plastic Deformation) processes, nanostructured and multilayered materials, and composites reinforced with dispersed particles. His contributions bridge fundamental theory with applied research in both manufacturing and advanced material development.

📘 Publications

📄 Modeling of Microstructure Evolution in Multiphase Steels under Dynamic Loading
👨‍🔬 Author: Janusz Majta
📘 Journal: Journal of Materials Processing Technology

📄 Multiscale Simulation of Severe Plastic Deformation in Ultrafine-Grained Alloys
👨‍🔬 Author: Janusz Majta
📘 Journal: Materials Science and Engineering A

📄 Computational Modeling of Thermomechanical Metal Forming Processes
👨‍🔬 Author: Janusz Majta
📘 Journal: International Journal of Mechanical Sciences

📄 Shear Band Instabilities in Polycrystalline Structures
👨‍🔬 Author: Janusz Majta
📘 Journal: Acta Materialia

📄 Physically Based Design of Metal-to-Metal Composites
👨‍🔬 Author: Janusz Majta
📘 Journal: Materials & Design

Dr Jiageng Guo | Microstructure and Properties | Best Researcher Award

Dr Jiageng Guo, Guangxi university of Chinese Medicine, China

Dr. Jiageng Guo is a distinguished researcher at Guangxi University of Traditional Chinese Medicine, specializing in pharmacology and cancer research. He has made significant contributions to liver cancer therapy, focusing on natural compounds like cinnamaldehyde and cinnamic acid. His work spans cutting-edge areas, including network pharmacology, bioinformatics, and both in vitro and in vivo experimental techniques. With high-impact publications in journals like Frontiers in Pharmacology, Dr. Guo integrates Traditional Chinese Medicine with modern pharmacology. His interdisciplinary approach offers innovative solutions for cancer therapy and drug discovery. 🌿🔬🧬💡📚

Publication Profile

Scopus

Skills

Guo Jiageng is highly skilled in network pharmacology and bioinformatics analysis, essential for understanding complex biological systems and drug interactions. He is proficient in various in vitro cell experimental techniques, including flow cytometry, cell proliferation, apoptosis, migration, invasion, and cell cycle analysis 🧬. Additionally, he has hands-on experience with in vivo experimental models, such as constructing zebrafish PDX models, performing zebrafish seahorse detection 🐟, and establishing mouse tumor-bearing models 🐭. These techniques are critical for advancing research in pharmacology and cancer therapy.

Education🎓

Dr. Guo is a distinguished academic at Guangxi University of Traditional Chinese Medicine, where he combines the rich heritage of traditional Chinese medicine with modern scientific research methodologies. His diverse academic background allows him to integrate a wide range of scientific knowledge, especially in the fields of pharmacology and holistic healing. With expertise in both traditional practices and contemporary research, Dr. Guo is well-positioned to explore and advance the understanding of Chinese medicine in the modern scientific landscape. His work bridges the gap between ancient wisdom and cutting-edge medical innovations. 🌿📚💡

Experience

From September 2022 to September 2024, Guo Jiageng dedicated his efforts to research on the therapeutic mechanisms of cinnamaldehyde and cinnamic acid in liver cancer treatment. His work explored crucial energy metabolism pathways and the EGFR pathway, aiming to uncover their potential in combating cancer cells 🧬. Through these studies, he contributed valuable insights into the molecular processes involved in liver cancer therapy, paving the way for novel treatments and therapeutic strategies 🍃.

Research Focus Area 🌱🧬

Dr. Jiageng Guo’s research primarily focuses on Traditional Chinese Medicine (TCM), pharmacology, and its applications in health restoration. His work includes investigating natural compounds like cinnamaldehyde 🌿 and Cinnamomi Cortex 🍃 for therapeutic effects, particularly in skin barrier restoration and cancer treatment. Dr. Guo explores the molecular mechanisms underlying these herbal treatments, such as the role of GSK-3β in liver cancer through the PI3K/AKT pathway ⚖️. His research bridges traditional herbal medicine with modern biomedical advancements 🩺, highlighting the potential of TCM in improving skin health and combating diseases.

Publication Top Notes📄✨

Insights from Traditional Chinese Medicine for Restoring Skin Barrier Functions

Visual analysis of knowledge graph for research progress on medicinal and edible traditional Chinese medicine Cinnamomi Cortex based on VOSviewer and CiteSpace

Evaluation of the effect of GSK-3β on liver cancer based on the PI3K/AKT pathway

Advances in pharmacological effects and mechanism of action of cinnamaldehyde

Conclusion🔍

Dr. Jiageng Guo is undoubtedly a suitable candidate for the Best Researcher Award, given his extensive research background, significant publications in top journals, mastery of diverse experimental techniques, and his impactful contributions to both modern cancer research and traditional medicine. His work is poised to make meaningful advancements in therapeutic development, particularly for liver cancer, and his multi-disciplinary approach offers considerable promise for future breakthroughs.