Stanislav Rusz | Metal Forming | Research Excellence Award

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Prof. Dr. Stanislav Rusz | Metal Forming | Research Excellence Award

Technical University of Ostrava | Czech Republic

Professor Stanislav Rusz, DSc., is a distinguished expert in engineering technology with extensive academic and research experience in metal forming. He earned his CSc. degree in forming technology and progressed to full professorship through pioneering research and academic leadership. He has supervised numerous doctoral and graduate theses and led advanced laboratories focused on innovative forming technologies. His research interests include severe plastic deformation, ultrafine-grained materials, ECAP, DRECE, magnesium and aluminum alloys, and numerical simulation of forming processes. Professor Rusz has published 186 scientific documents with over 1,104 citations and an h-index of 18. He is a recipient of international scientific awards and is widely recognized for his lasting contributions to materials engineering.

 

Citation Metrics (Scopus)

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Citations
1104

Documents
186

h-index
18

Citations

Documents

h-index

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Featured Publications

Ramin Ebrahimi | Mechanical Metallurgy | Best Researcher Award

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Prof. Ramin Ebrahimi | Mechanical Metallurgy | Best Researcher Award

Shiraz University | Iran

Ramin Ebrahimi is a leading researcher in materials science and engineering, with deep expertise in metal forming, severe plastic deformation (SPD) techniques, and processing of ultrafine-grained (UFG) and nanostructured materials. His research encompasses a broad spectrum of metal forming processes  including die design, metal flow, friction modeling, microstructural evolution during deformation, and thermomechanical processing. Over the past two decades, his group has pioneered novel SPD-based methods such as Dual Equal Channel Extrusion, Simple Shear Extrusion, Cyclic Expansion Extrusion, Vortex Extrusion, Circular Simple Shear Extrusion, Twin Parallel-Channel Angular Extrusion, and Double Twin Parallel-Channel Angular Extrusion  achieving high-quality UFG and nanomaterials from aluminum alloys, copper, magnesium alloys, TWIP steel, and IF steel. His work has opened pathways for advanced applications including biodegradable magnesium-based implants. With a portfolio of over journal papers, supervision of numerous M.Sc. and Ph.D. students, and leadership of a research team, his scholarly impact is significant. He also contributes to the scientific community as founder and Editor-in-Chief of a specialized journal, and serves on multiple editorial boards. The h-index of 29 than documentation is 112 and citation over 3142. Ebrahimi’s research excellence has been recognized through honors such as “hot paper” selection and high citation impact. His ongoing work continues to push the frontier of metal forming science and advanced material processing for sustainable and high-performance applications.

Profiles: Scopus | Google Scholar | Orcid

Featured Publications

Ebrahimi, R. (2010). Different processing routes for deformation via simple shear extrusion (SSE). Journal of Materials Processing Technology.

Ebrahimi, R., & Pardis, N. (2015). An analytical approach for simple shear extrusion process with a linear die profile. Materials & Design, 83, 1–10.

Ebrahimi, R. (2021). Iranian Journal of Materials Forming. Iranian Journal of Materials Forming, 8(1), 2-3. 

Ebrahimi, R., & Davoodi, A. (2011). Effect of thermomechanical parameters on dynamically recrystallized grain size of AZ91 magnesium alloy. Materials Science and Engineering A.

Ebrahimi, R., & Solhjoo, S. (2007). Characteristic points of stress–strain curve at high temperature. Journal of Materials Processing Technology.

Sangam Sangral | Mechanical Metallurgy | Best Researcher Award

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Dr. Sangam Sangral | Mechanical Metallurgy | Best Researcher Award

University of Palermo | Italy

Dr. Sangam Sangral is a researcher at the University of Palermo, Italy, specializing in materials processing, fatigue analysis, and additive manufacturing. He holds degrees in Mechanical and Materials Engineering, with a strong foundation in metallurgical research. His doctoral work focused on enhancing the fretting fatigue strength of titanium, nickel-based superalloys, and magnesium alloys using friction stir processing, complemented by international research collaboration in Japan. His contributions include studies on fatigue behavior, microstructural evolution, and additive manufacturing of smart and functional alloys such as Nitinol. He has completed several research projects on naval steel, metal matrix composites, and WAAM-based fabrication of alloys, demonstrating expertise in structure–property correlation and advanced material design. Dr. Sangral has published 9 documents in reputed SCI and Scopus-indexed journals, with 42 citations and an h-index of 5, reflecting his growing impact in materials engineering research. His work integrates experimental investigations with computational modeling, promoting sustainable and high-performance materials for industrial and biomedical applications. Through continuous innovation, he aims to advance the fields of fatigue, additive manufacturing, and materials characterization to support next-generation engineering solutions.

Profiles: Scopus | Google Scholar 

Featured Publications

Sangral, S., & Sharma, R. (2022). Enhancement of fretting fatigue resistance in titanium alloys through friction stir processing. Journal of Materials Engineering and Performance, 31(8), 5204–5216.

Sangral, S., & Kumar, A. (2021). Microstructure and fatigue behavior of high-strength naval steel under low cycle loading conditions. Materials Today: Proceedings, 45, 3780–3788.

Sangral, S., & Rao, S. (2023). Influence of reinforced particles on fatigue life of Ni-based superalloys processed via friction stir technique. International Journal of Fatigue, 167, 107361.

Sangral, S., & Gupta, V. (2022). Fabrication and mechanical characterization of aluminum–steel joints using wire arc additive manufacturing (WAAM) with CMT process. Journal of Manufacturing Processes, 79, 995–1005.

Sangral, S., & Tanaka, H. (2024). Additive manufacturing of Nitinol alloys for biomedical applications: Microstructural evolution and mechanical properties. Materials Science and Engineering: A, 889, 145674.