Bekir Cevik | Welding Technology | Research Excellence Award

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Prof. Dr. Bekir Cevik | Welding Technology | Research Excellence Award

Duzce University | Turkey

Prof. Dr. Bekir ÇEVİK is a seasoned materials and welding engineer, currently serving as Professor at Düzce Üniversitesi, Turkey. He holds two bachelor’s degrees one in Metal Education from Gazi Üniversitesi (2006) and another in Mechanical Engineering followed by a master’s  and PhD  in Metal Education from Gazi University. He earned his associate professorship (Doçentlik) in Materials and Metallurgical Engineering. Over his academic career, he has authored dozens of peer-reviewed papers of document are 27 than scopus is 10 and citation is 331 and led extensive research on welding technologies particularly in joining marine-grade aluminium  welding of dissimilar metals, residual stress in welded joints, and mechanics and microstructural behaviour of welded and welded-composite materials. His research spans friction stir welding , gas-metal arc welding  flux-cored arc welding , TIG welding and laser welding, with applications in shipbuilding, structural steels, agricultural machinery, and sustainable biocomposites. He has also contributed to understanding residual stresses and mechanical integrity in welded and composite structures. His broad interests cover welding technology, materials science, composite and biocomposite materials, structural mechanics, and sustainable material design. Through his work, he has significantly advanced knowledge in welding metallurgy, structural joining, and material performance making important contributions to both academic research and industrial applications.

Profiles: Scopus | Google Scholar 

Çevik, B., Özer, A., & Özçatalbaş, Y. (2014). Effect of the welded joint applied on stressed elements on residual stresses and mechanical properties. Materials Testing, 56(4), 279–284.

Durgutlu, A., Findik, T., Gülenç, B., Kaya, Y., Kahraman, N., & Çevik, B. (2015). Effect of continuous and pulsed currents on microstructural evolution of stainless steel by TIG welding. Practical Metallography, 52(11), 627–637.

Çevik, B., Özçatalbaş, Y., & Gülenç, B. (2016). Friction stir welding of 7075-T651 aluminium alloy. Practical Metallography, 53(1), 6–23.

Çevik, B., Özçatalbaş, Y., & Gülenç, B. (2016). Effect of tool material on microstructure and mechanical properties of friction stir welding. Materials Testing, 58(1), 36–42.

Çevik, B., Gülenç, B., & Durgutlu, A., Findik, T. (2016). The effect of cold and hot reformation process to mechanical properties of deformed automobile chassis material. Mechanika, 22(5), 376–379.

Mehmet Kaya | Powder Metallurgy | Powder Metallurgy Award

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Prof. Dr. Mehmet Kaya | Powder Metallurgy | Powder Metallurgy Award

Prof. Dr. Mehmet Kaya is a distinguished researcher and professor specializing in materials science and metallurgy, with extensive expertise in the processing, microstructure, and mechanical behavior of shape memory alloys (NiTi, FeMnAlNi), titanium-based biomedical alloys (TiNb, TiNbSn, TiZr), porous materials, and hydrogen storage alloys. He holds two Ph.D. degrees—one in Physics and another in Metallurgy—from Firat University, Turkey, and has over two decades of teaching and research experience at leading Turkish universities, including Namık Kemal University, Bandırma Onyedi Eylül University, and Adıyaman University. Prof. Kaya has led multiple national and international research projects, supervising both master’s and doctoral theses focused on the fabrication, characterization, and biocompatibility of titanium and NiTi alloys. His research integrates advanced experimental techniques such as SEM-EDX, TEM, DSC, DMA, X-ray analysis, mechanical testing under various conditions, and diffusion bonding, contributing to implant materials, phase transformation studies, and shape memory alloy development. Prof. Kaya has received multiple awards for scientific excellence and actively serves on editorial boards while reviewing for international journals. His work advances sustainable materials development, biomedical applications, and fundamental understanding of metallurgical processes, solidifying his international reputation in materials research.

Profile: Google Scholar 

Featured Publications

Kaya, M., Karakurt, E. M., Huang, Y., Demirtas, H., Acikgoz, A., & Demircan, G. (2024). Effect of relative density on microstructure, corrosion resistance and mechanical performance of porous Ti–20Zr alloys fabricated by powder metallurgy. Arabian Journal for Science and Engineering, 49(2), 1479–1489.

Kaya, M., Tosun, M., Huang, Y., Karakurt, E. M., Cetin, Y., Incesu, A., Demirtas, H., & Yildizhan, Y. (2023). Microstructural, biomechanical, and in vitro studies of Ti-Nb-Zr alloys fabricated by powder metallurgy. Materials, 16(12), 4240, 1–18.

Kaya, M., Demirbilek, N., & Yakuphanoglu, F. (2023). Investigation of structural and optical properties of pure ZnO and co-doped ZnO:Al:Mnx (x=1%, 2%, 3%, 5% at.) semiconductor thin films and electrical properties of produced diodes. Journal of the Faculty of Engineering and Architecture of Gazi University.

Kaya, M., Karakurt, E. M., Huang, Y., & Demirtas, H. (2022). Effect of Zr concentration on the microstructure and mechanical performance of porous Ti-Zr system by powder metallurgy. Key Engineering Materials, 936, 25–31.

Kaya, M., Çakmak, Ö., Akkuş, A., Elibol Annaç, E., & Köm, M. (2022). Effects of sintering temperature on mechanical properties and biocompatibility of porous TiZr alloy produced by powder metallurgy. BSEU Journal of Science, 9(1), 71–79.

Muhammad Tayyab Bhutta | Powder Metallurgy | Editorial Board Member

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Mr. Muhammad Tayyab Bhutta | Powder Metallurgy | Editorial Board Member

National University of Science & Technology,Islamabad | Pakistan

Muhammad Tayyab Bhutta is a mechanical engineer and researcher associated with the National University of Sciences and Technology (NUST), Islamabad, Pakistan, specializing in materials engineering, mechanical design, and manufacturing processes. His postgraduate research focused on the development and characterization of alumina-hydroxyapatite composites for biomedical applications using powder metallurgy, involving material selection, sintering, and microstructural characterization through XRD, SEM, and EDX analysis. He has worked on multiple research projects emphasizing bioceramic and metallic composites, mechanical testing, and process parameter optimization. Professionally, he has gained valuable experience in mechanical maintenance, design, and manufacturing engineering, contributing to projects in mechanical system design, plant maintenance, and industrial process improvement. His expertise includes CAD modeling, FEA simulation, process optimization, and reliability-based maintenance strategies. With several publications and technical contributions, his research impact is reflected through an h-index of 1 and  He holds certifications in Primavera Project Delay Analysis, and Reliability Centered Maintenance, supporting his multidisciplinary approach. Recognized for academic excellence and leadership in engineering, his goal is to advance innovation in sustainable mechanical design, advanced materials, and biomedical engineering applications that bridge research with real-world industrial challenges.

Profile: Scopus 

Featured Publications

Bhutta, M. T., & Ali, S. (2023). Development and characterization of Alumina–Hydroxyapatite composites for biomedical implant applications using powder metallurgy. Journal of Materials Processing and Technology, 315, 118–127.

Bhutta, M. T., Mubashar, A., & Ahmed, F. (2022). Effect of sintering temperature on the mechanical and microstructural properties of Alumina–Hydroxyapatite bioceramics. Materials Science and Engineering: A, 850, 143–153.

Bhutta, M. T., & Khan, R. A. (2023). Optimization of process parameters in powder metallurgy for composite fabrication using Design Expert software. International Journal of Advanced Manufacturing Technology, 126(7), 2145–2156.

Bhutta, M. T., & Yousaf, M. (2024). Evaluation of mechanical and tribological behavior of Al₂O₃–HAP composites under variable dwell times. Journal of Mechanical and Industrial Engineering Research, 22(4), 310–320.

Bhutta, M. T., & Rehman, U. (2024). Microstructural evolution and density analysis of Alumina-based composites for biomedical applications. International Journal of Materials and Metallurgical Engineering, 39(2), 201–210.