Xin Bai | Mechanical Engineering | Best Researcher Award

Posted on by sciencefather

Assist. Prof. Dr. Xin Bai | Mechanical Engineering
|Best Researcher Award

Assist. Prof. Institute of Metal Research, Chinese Academy of Sciences, China.

 

Assoc. Prof. Dr. Xin Bai is a distinguished researcher at the Institute of Metal Research, Chinese Academy of Sciences, and a member of the Youth Innovation Promotion Association. Renowned for his pioneering work in fatigue fracture and structural reliability, Dr. Bai has significantly advanced methods for predicting fatigue performance from minimal experimental data. His research is both innovative and impactful, addressing critical needs in materials engineering and structural integrity. His commitment to developing cost-effective and efficient reliability assessment tools and software has garnered recognition across academia and industry. Dr. Bai’s sustained research excellence, leadership, and contributions to cutting-edge reliability science make him a compelling candidate for the Best Researcher Award.

🌍 Professional Profile:

Orcid

🏆 Suitability for the Best Researcher Award

 

Assoc. Prof. Dr. Xin Bai is a distinguished researcher at the Institute of Metal Research, Chinese Academy of Sciences, and a member of the Youth Innovation Promotion Association. Renowned for his pioneering work in fatigue fracture and structural reliability, Dr. Bai has significantly advanced methods for predicting fatigue performance from minimal experimental data. His research is both innovative and impactful, addressing critical needs in materials engineering and structural integrity. His commitment to developing cost-effective and efficient reliability assessment tools and software has garnered recognition across academia and industry. Dr. Bai’s sustained research excellence, leadership, and contributions to cutting-edge reliability science make him a compelling candidate for the Best Researcher Award.

🎓 Education 

Dr. Xin Bai received comprehensive training in materials science and engineering, culminating in his doctoral studies at the prestigious Institute of Metal Research, Chinese Academy of Sciences (CAS). His academic path reflects a strong foundation in mechanical behavior, fracture mechanics, and fatigue analysis. He has also engaged in postdoctoral research and advanced studies in failure physics, enhancing his expertise in structural reliability. His educational journey combined rigorous scientific coursework with hands-on research in laboratory environments, allowing him to acquire the necessary skills for leading complex experimental and theoretical investigations. His continued affiliation with CAS exemplifies the high caliber of his education and research orientation.

🏢 Work Experience 

Dr. Xin Bai serves as an Associate Professor at the Institute of Metal Research, Chinese Academy of Sciences, and is actively involved in advanced fatigue and reliability studies. His professional journey includes extensive experience in developing fatigue reliability methods based on physical failure mechanisms, small-scale testing, and predictive modeling. He has led multiple research projects focusing on translating laboratory-scale data into accurate, full-scale structural performance assessments. His work integrates mechanical engineering, software development, and statistical modeling to address real-world engineering problems. As a member of the Youth Innovation Promotion Association of CAS, he collaborates with leading scientists nationwide, contributing to China’s strategic goals in materials reliability and engineering safety.

🏅 Awards and Honors 

Dr. Xin Bai has been honored as a member of the Youth Innovation Promotion Association of the Chinese Academy of Sciences—an elite recognition awarded to promising young scientists. This distinction underscores his contributions to material reliability and fatigue research. He has received accolades for his innovative research methods and impactful findings, with invitations to present at top conferences and collaborations with national-level research teams. His software development efforts for fatigue prediction have been adopted in academic and industrial settings, further establishing his influence in the field. His work continues to earn national and institutional praise, positioning him among China’s rising stars in materials science and engineering.

🔬 Research Focus 

Dr. Xin Bai’s research centers on developing low-cost, high-efficiency methods for assessing fatigue reliability based on failure physics. His focus areas include: (1) structural fatigue reliability assessment using minimal testing data, enabling accurate predictions without extensive experimentation; (2) techniques for extrapolating full-scale component fatigue performance from small specimen data, significantly reducing testing time and cost; and (3) software development to support fatigue fracture analysis and reliability modeling. His interdisciplinary approach combines materials science, mechanical engineering, and data-driven modeling to advance the understanding and prediction of structural behavior under cyclic loads. His innovations have broad applications in aerospace, automotive, and infrastructure industries, helping ensure long-term structural safety and performance.

📊 Publication Top Notes:

  • Song Zhou; Zhaoxing Qian; Xin Bai (2024). Static properties evaluation for laser deposition repaired TA15 components based on a constitutive model considering annealing heat treatment. Engineering Failure Analysis.

  • Xin Bai; Peng Zhang; Shuo Liu; Rui Liu; Bingfeng Zhao; Zhefeng Zhang (2023). Fatigue strength prediction of large-size component through size effect measurement and determination. International Journal of Fatigue.

  • X. Bai; P. Zhang; Q. Wang; R. Liu; Z. J. Zhang; Q. Q. Duan; E. N. Yang; H. Bo; Z. F. Zhang (2022). A New Dominance Distribution Method to Select Materials with Higher Fatigue Resistance under Property Scatter and Load Uncertainty. Journal of Materials Engineering and Performance.

  • Zhiming Xie; Peng Wang; Bin Wang; P. Zhang; Xin Bai; Zhefeng Zhang (2022). Effects of Heat Treatment on Fatigue Properties of Double Vacuum Smelting High‐Carbon Chromium‐Bearing Steel. Advanced Engineering Materials.

  • Shuo LIU; Bin Wang; P. Zhang; Xin Bai; Qiqiang Duan; Xuegang Wang; Zhefeng Zhang (2022). The Effect of Microstructure Inhomogeneity on Fatigue Property of EA4T Axle Steel. steel research international.

  • Bingfeng Zhao; Liyang Xie; Yu Zhang; Jungang Ren; Xin Bai; Bo Qin (2021). An improved dynamic load-strength interference model for the reliability analysis of aero-engine rotor blade system. Journal of Aerospace Engineering.

  • Lei Wang; Bingfeng Zhao; Lei Wang; Zhiyong Hu; Song Zhou; Xin Bai (2021). A new multiaxial fatigue life prediction model for aircraft aluminum alloy. International Journal of Fatigue.

  • Xin Bai; Peng Zhang; Enna Yang; Qiqiang Duan; Hao Bo; Zhefeng Zhang (2020). Dominance distributions for fatigue performance of materials and its application in material selection. Preprint on Authorea.

  • Xin Bai; Peng Zhang; Zhen‐jun Zhang; Rui Liu; Zhe‐feng Zhang (2019). New method for determining P‐S‐N curves in terms of equivalent fatigue lives. Fatigue & Fracture of Engineering Materials & Structures.

  • Xin Bai; Liyang Xie; Ruijin Zhang; Ruoyi Guan; Anshi Tong; Enjun Bai (2017). Measurement and estimation of probabilistic fatigue limits using Monte-Carlo simulations. International Journal of Fatigue.

Harun YANAR | Mechanical Engineering | Best Researcher Award

Posted on by sciencefather

Assist. Prof. Dr. Harun YANAR | Mechanical Engineering
|Best Researcher Award

Assist. Prof. Dr at  Karadeniz Technical University, Turkey.

 

Dr. Harun Yanar is an Assistant Professor at Karadeniz Technical University, Department of Mechanical Engineering. Specializing in materials science and tribology, he holds a Ph.D. (2020) in Mechanical Engineering. Dr. Yanar is the founder of UTS Scientific Instruments Co., connecting academia with industrial innovation. His research explores severe plastic deformation (SPD) techniques, ultrafine-grained and nanostructured materials, tribology, and superplasticity. He has authored over 20 SCI-indexed journal articles and led several national research projects funded by TUBITAK. With an h-index of 13 in both WoS and Scopus, he significantly contributes to advanced materials engineering. Dr. Yanar also actively mentors graduate students and serves as a reviewer for leading international journals, advancing research and practical solutions in material performance and durability.

🌍 Professional Profile:

Google scholar

Scopus

Orcid

🏆 Suitability for the Best Researcher Award

 

Dr. Harun Yanar is exceptionally suited for the Best Researcher Award due to his pioneering contributions in materials science and mechanical engineering. His expertise in severe plastic deformation techniques, tribological system design, and microstructural property optimization demonstrates scientific excellence and innovation. His prolific research output, with over 20 publications in top SCI-indexed journals and an h-index of 13, reflects high academic impact. Additionally, his leadership in TUBITAK-funded research projects, mentorship of graduate students, and commitment to bridging research and industry through UTS Scientific Instruments Co. highlight his outstanding versatility. Dr. Yanar’s work on superplasticity, wear behavior, and performance enhancement of engineering materials addresses critical industrial challenges, making him a deserving candidate for this prestigious recognition.

🎓 Education 

Dr. Harun Yanar’s educational journey is rooted in mechanical engineering and materials science. He completed his undergraduate and master’s studies with distinction before earning his Ph.D. in Mechanical Engineering in 2020 from Karadeniz Technical University. His doctoral research focused on severe plastic deformation (SPD) techniques and their impact on mechanical properties, setting the stage for his future contributions to advanced material design. Dr. Yanar’s education is marked by a strong foundation in mechanical behavior analysis, metallurgy, and tribology. His rigorous academic training provided the skills necessary for cutting-edge research in microstructural evolution, superplasticity, and high-performance engineering materials. His educational achievements have consistently aligned with international standards, preparing him for academic leadership and technological innovation.

🏢 Work Experience 

Dr. Harun Yanar brings extensive academic and industrial experience to his field. As an Assistant Professor at Karadeniz Technical University, he has spearheaded multiple national research projects, mentored graduate students, and designed tribological testing systems. His industrial engagement is evident through his role as founder of UTS Scientific Instruments Co., where he facilitates technology transfer from research to practical applications. Dr. Yanar’s research experience spans severe plastic deformation processes, ultrafine-grained material development, and tribological behavior optimization. His dual role in academia and industry provides him with a comprehensive perspective on material performance challenges. Furthermore, his editorial contributions as a peer reviewer for high-impact journals reinforce his commitment to maintaining scientific rigor and promoting the advancement of materials engineering.

🏅 Awards and Honors 

Dr. Harun Yanar’s dedication to research excellence has been recognized through various accolades. While specific awards were not detailed, he has been acknowledged through his leadership roles in TUBITAK-funded projects and significant national research grants. His outstanding publication record, with over 20 SCI-indexed journal papers and a robust citation profile (h-index of 13 in both WoS and Scopus), reflects his recognized contributions to materials science and mechanical engineering. Dr. Yanar’s expertise in tribology, SPD techniques, and superplasticity has earned him respect within the academic and industrial communities. His successful bridging of theoretical research and practical innovation further exemplifies his impact. Future recognitions and nominations, such as the Best Researcher Award, continue to affirm his leadership in engineering research.

🔬 Research Focus 

Dr. Harun Yanar’s research focus centers on the development of advanced materials through severe plastic deformation (SPD) techniques, tribological system design, and microstructure-property optimization. He investigates friction, wear, and lubrication behaviors, particularly under extreme operating conditions, and the mechanical enhancement of ultrafine-grained and nanostructured materials. His studies extend to exploring superplasticity at lower temperatures and higher strain rates, which has significant implications for manufacturing and aerospace applications. Dr. Yanar also specializes in the development and testing of high-performance brake lining materials and surface modification processes. His work bridges the fundamental understanding of materials science with industrial applications, offering practical solutions to challenges in durability, performance, and reliability of mechanical systems.

📊 Publication Top Notes:

  • Harun Yanar, Abdulkadir Coskun (2025). Influence of multi directional forging-induced grain refinement and subsequent aging on tribological performance of Cu-Ni-Si-Cr Alloys in Electrical Contact Sliding Conditions. Wear, In Press.

  • Muhammet Demirtas, Harun Yanar, Muhammet Uzun, Melih Ustalar, Zhenjun Zhang, Renjie Dai, Jiewen Jin, Gencaga Purcek (2025). Effect of Severe Plastic Deformation and Aging States on Microstructure and Mechanical Properties of 2024 Aluminum Alloy. Advanced Engineering Materials, 2402728.

  • Hao Wang, ZhenJun Zhang, BaiShan Gong, XiangHai Zhou, Rui Liu, Hamid Reza Abedi, Gencaga Purcek, Harun Yanar, Muhammet Demirtas, ZheFeng Zhang (2024). High-Cycle-Fatigue Anisotropy of an Aluminum Alloy Superthick Plate. Advanced Engineering Materials, 26, 2400007.

  • Hao Wang, Z.J. Zhang, J.P. Hou, B.S. Gong, H.Z. Liu, H.R. Abedi, G. Purcek, H. Yanar, M. Demirtas, Z.F. Zhang (2024). Fatigue crack propagation anisotropy of an Al–Zn–Mg–Cu super-thick plate. International Journal of Fatigue, 187, 108468.

  • M. Demirtas, K.V. Ivanov, G. Purcek, H. Yanar, Y. Kaynak (2024). Surface Modification of Additively Manufactured Inconel 718 Alloy by Low-Energy High-Current Electron Beam Irradiation. Advanced Engineering Materials, 26, 2400633.

  • B. Gong, Z. Zhang, J. Hou, R. Liu, Q. Duan, H. Wang, X. Wang, H. Liu, H. Wang, G. Purcek, M. Demirtas, H. Yanar, Z. Zhang (2024). Effects of aging state on the low-cycle fatigue properties of 2024 aluminum alloy. Journal of Materials Research and Technology, 29, 2448–2457.

  • M. Demirtas, K.V. Ivanov, G. Purcek, H. Yanar (2022). Enhancing mechanical and tribological properties of Ni₃Al–15 vol% TiC composite by high current pulsed electron beam irradiation. Journal of Alloys and Compounds, 898, 162860.

  • H. Yanar, G. Purcek, M. Demirtaş, H.H. Ayar (2022). Effect of Hexagonal Boron Nitride (h-BN) Addition on Friction Behavior of Low-Steel Composite Brake Pad Material for Railway Applications. Tribology International, 165, 107274.

  • G. Purcek, H. Yanar, M. Demirtaş, D.V. Shangina, N.R. Bochvar, S.V. Dobatkin (2020). Microstructural, mechanical and tribological properties of ultrafine-grained Cu–Cr–Zr alloy processed by high pressure torsion. Journal of Alloys and Compounds, 816, 152675.

  • H. Yanar, H.H. Ayar, M. Demirtaş, G. Purcek (2020). Effect of resin content on tribological behaviour of brake pad composite material. Industrial Lubrication and Tribology, 72(2), 195–2002.