Harun Mindivan | Titanium Alloy | Best Researcher Award

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Prof. Dr. Harun Mindivan | Titanium Alloy | Best Researcher Award

Professor at Bilecik Seyh Edebali University | Turkey

This researcher has established a distinguished scientific profile in materials science and mechanical engineering, with a strong emphasis on tribology, surface modification, and advanced coating technologies. With 612 citations, 52 Scopus-indexed documents, and an h-index of 13, their research impact is well recognized within the global scientific community. Their work centers on developing high-performance materials and engineered surfaces capable of withstanding extreme mechanical, thermal, and corrosive environments. They have contributed extensively to the development of plasma-nitrided steels, electroless and electrochemical borided alloys, graphene-enhanced composite coatings, high-velocity oxy-fuel (HVOF) sprayed stainless steel coatings, and oxide-reinforced thin films. Through comprehensive analyses of microstructure–property relationships, the researcher advances understanding of wear mechanisms, tribocorrosion behavior, hardness enhancement, and coating adhesion in metallic systems. Their investigations on metal–matrix composites-such as carbon-nanotube-reinforced aluminum and magnesium-offer significant innovations in lightweight structural materials. Additional contributions include studies on surface optimization of titanium alloys, corrosion-resistant coatings, and improvements in machinability and mechanical integrity of industrial steels. Their research outputs are consistently published in reputable scientific journals indexed in Scopus and other major databases, demonstrating steady productivity and high citation engagement. By integrating experimental surface engineering methods with performance evaluation techniques, the researcher provides actionable scientific advancements that support the development of durable engineering materials. This strong publication record and sustained contribution across multiple material systems highlight the researcher’s ongoing significance and excellence in the field.

Profiles : Scopus | ORCID | Google Scholar

Featured Publications

Mindivan, H., Kayali, E. S., & Cimenoglu, H. (2008). Tribological behavior of squeeze cast aluminum matrix composites. Wear, 265(5–6), 645–654.

Mindivan, H., Efe, A., Kosatepe, A. H., & Kayali, E. S. (2014). Fabrication and characterization of carbon nanotube reinforced magnesium matrix composites. Applied Surface Science, 318, 234–243.

Mindivan, H., Çimenoğlu, H., & Kayali, E. S. (2003). Microstructures and wear properties of brass synchroniser rings. Wear, 254(5–6), 532–537.

Mindivan, H., Baydogan, M., Kayali, E. S., & Cimenoglu, H. (2005). Wear behaviour of 7039 aluminum alloy. Materials Characterization, 54(3), 263–269.

Mindivan, H. (2010). Reciprocal sliding wear behaviour of B₄C particulate reinforced aluminum alloy composites. Materials Letters, 64(3), 405–407.

Fu Lei | Corrosion Fatigue | Best Researcher Award

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Prof. Fu Lei | Corrosion Fatigue | Best Researcher Award

Professor at Sichuan University of Science & Engineering | China

Professor Fu Lei, a distinguished materials scientist at Sichuan University of Science and Engineering, specializes in fatigue, fracture, and structural reliability of metallic systems. His research bridges experimental and computational mechanics, focusing on failure prediction, damage evolution, and fatigue-corrosion interactions in advanced alloys and composites. He has led more than 30 national and regional projects, notably under the National Natural Science Foundation of China, covering aerospace, nuclear, and new-energy applications. His Scopus record lists 32 documents, 127 citations, and an h-index of 7, demonstrating sustained scientific impact. His studies on hydrogen-induced fracture, micro-defect propagation, and microbiologically influenced corrosion have refined theoretical and experimental understanding of structural materials under coupled stresses. Beyond research, he has authored a monograph and contributed to developing fatigue-testing standards and additive-manufacturing methods for UAV composites and biomedical implants. Serving as Deputy Director of multiple provincial research centers, he fosters collaborative R&D between academia and industry, enabling technology transfer in functional materials and mechanical systems. Professor Fu’s integrated approach to mechanics, reliability engineering, and materials innovation underscores his global leadership and positions him as a top candidate for recognition under the Best Researcher Award.

Profiile : Scopus

Featured Publications

Fu, L., et al. (2025). Experimental study of the hydrogen fracture behavior of 30CrMo steel and simulation of hydrogen diffusion. JOM, [Advance online publication].

Fu, L., et al. (2025). Modification of graphene oxide composite coating on 7075 aluminum alloy and protection against Aspergillus niger corrosion. Anti-Corrosion Methods and Materials, [Advance online publication].

Fu, L., et al. (2025). Mechanics and long-term stability of porous titanium scaffolds with rhombic dodecahedrons. Journal of Materials Engineering and Performance, [Advance online publication].

 

Qi Shi | Refractory Metals | Best Researcher Award

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Qi Shi | Refractory metals | Best Researcher Award

Senior Engineer at Ningbo University of Technology | China

Assoc. Prof. Dr. Qi Shi is a distinguished researcher in materials science with a Ph.D. in Materials Science and Technology from Loughborough University, UK. Since returning to China, he has focused on the R&D of near-net-shape technologies, including advanced metal powders, powder metallurgy, and additive manufacturing. His pioneering work in radio-frequency (RF) plasma spheroidization of refractory metals has achieved breakthroughs in stable feeding technology for ultrafine powders, enabling consistent feeding and effective dispersion of low-density powders. He has also developed ultrasonic-fluidized bed wet classification methods for efficient micro-nano powder separation, leading to the production and commercialization of low-oxygen tantalum powder, ultrafine tungsten powder, and ultra-high hardness cast tungsten carbide powder. His research extends to metal additive manufacturing and post-processing, where he has advanced powder suitability evaluation and clarified the role of powder characteristics in selective laser melting (SLM). Through hot isostatic pressing and high-pressure heat treatment, he has enhanced strength–toughness synergy and significantly improved high-cycle fatigue performance in stainless steel, tantalum, and tungsten. Qi Shi has led five major government-funded projects, securing over RMB three million, and contributed to more than ten additional national and regional initiatives. He has published 35 academic papers in prestigious journals such as Additive Manufacturing, Materials Science and Engineering: A, and Journal of Materials Research and Technology, including 15 as first or corresponding author. According to his Scopus profile, he has more than 356 citations and an h-index of 13. He has also applied for 21 patents (15 granted), contributed to national standards, authored professional books, and received multiple awards, including the China Nonferrous Metals Industry Science and Technology Award (Second Prize) and the National Technical Standard Excellence Award (First Prize).

Profile: Scopus

Featured Publications

Shi, Q., Li, D., Du, W., Wu, A., & others. (2024). Improved mechanical properties and thermal conductivity of laser powder bed fused tungsten by using hot isostatic pressing. Cited by: 2

Pu, Y., Zhao, D., Liu, B., Shi, Q., & others. (2024). Microstructure evolution and mechanical properties of Ti-25Ta alloy fabricated by selective laser melting and hot isostatic pressing. Cited by: 1

Xu, J., Chen, H., Shi, Q., Liu, X., & others. (2024). Interdiffusion mechanism of hybrid interfacial layers for enhanced electrical resistivity and ultralow loss in Fe-based nanocrystalline soft magnetic composites. Cited by: 3

Qin, F., Shi, Q., Zhou, G., Wen, J., & others. (2024). Simultaneously enhanced strength and plasticity of laser powder bed fused tantalum by hot isostatic pressing. Cited by: 2

Qin, F., Shi, Q., Zhou, G., Yao, D., & others. (2023). Influence of powder particle size distribution on microstructure and mechanical properties of 17-4 PH stainless steel fabricated by selective laser melting. Cited by: 14