Wenbo Yu | Materials | Best Researcher Award

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Prof. Wenbo Yu | Materials | Best Researcher Award

Prof. Wenbo Yu | Materials | Director at Beijing Jiaotong University | China

Prof. Wenbo Yu is a highly accomplished scholar and researcher in the field of Materials Science and Engineering, currently serving as a Professor at Beijing Jiaotong University, China. With a strong academic foundation and global research exposure, Prof. Wenbo Yu has made remarkable contributions to the synthesis, processing, and performance optimization of ceramic and composite materials. He earned his Ph.D. in Materials Science from Université de Poitiers, France, where he conducted advanced studies on the synthesis and mechanical properties of ceramics under the supervision of Professors Sylvain Dubois and Véronique Gauthiers. Prior to that, he obtained his Master’s and Bachelor’s degrees in Materials Science from Beijing Jiaotong University and Changsha University of Science and Technology, respectively. Prof. Wenbo Yu has held several significant academic positions, including Associate Professor and Postdoctoral Researcher at Tsinghua University, where his work focused on material forming and mechanical performance improvement. His research interests include ceramic composites, nanolaminated materials, MAX and MAB phases, thermal shock resistance, and additive manufacturing. With strong research skills in material synthesis, microstructural characterization, and mechanical analysis, he has authored more than 60 SCI-indexed papers with over 1,000 citations and an H-index of 22. His groundbreaking work has appeared in top journals such as Acta Materialia, Journal of the European Ceramic Society, and Journal of Alloys and Compounds. Prof. Wenbo Yu has been honored with prestigious recognitions, including the Beijing Rail Transit Outstanding Youth Talent Award and the Machinery Industry Award for innovation in high-pressure die casting. Through his teaching, research leadership, and collaboration, he has contributed significantly to the advancement of materials science both in academia and industry. In conclusion, Prof. Wenbo Yu stands as a leading figure in his field, dedicated to pioneering new frontiers in sustainable and high-performance materials research.

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Featured Publications

  1. Hu, J., Li, S., Zhang, J., Chang, Q., Yu, W., & Zhou, Y. (2020). Mechanical properties and frictional resistance of Al composites reinforced with Ti₃C₂Tx MXene. Chinese Chemical Letters, 31(4), 996–999. (Cited by 122)

  2. Li, S. B., Yu, W. B., Zhai, H. X., Song, G. M., Sloof, W. G., & Van der Zwaag, S. (2011). Mechanical properties of low temperature synthesized dense and fine-grained Cr₂AlC ceramics. Journal of the European Ceramic Society, 31(1–2), 217–224. (Cited by 119)

  3. Yu, W., Wang, X., Zhao, H., Ding, C., Huang, Z., Zhai, H., Guo, Z., & Xiong, S. (2017). Microstructure, mechanical properties and fracture mechanism of Ti₂AlC reinforced AZ91D composites fabricated by stir casting. Journal of Alloys and Compounds, 702, 199–208. (Cited by 94)

  4. Yu, W., Li, S., & Sloof, W. G. (2010). Microstructure and mechanical properties of a Cr₂Al(Si)C solid solution. Materials Science and Engineering: A, 527(21–22), 5997–6001. (Cited by 89)

  5. Lu, X., Li, S., Zhang, W., Yao, B., Yu, W., & Zhou, Y. (2019). Crack healing behavior of a MAB phase: MoAlB. Journal of the European Ceramic Society, 39(14), 4023–4028. (Cited by 87)

  6. Yu, W., Mauchamp, V., Cabioc’h, T., Magne, D., Gence, L., Piraux, L., & Dubois, S. (2014). Solid solution effects in the Ti₂Al(CxNy) MAX phases: Synthesis, microstructure, electronic structure and transport properties. Acta Materialia, 80, 421–434. (Cited by 77)

  7. Lu, X., Li, S., Zhang, W., Yu, W., & Zhou, Y. (2019). Thermal shock behavior of a nanolaminated ternary boride: MoAlB. Ceramics International, 45(7), 9386–9389. (Cited by 75)

 

Dora Zakarian | Materials Science | Best Researcher Award

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Dr. Dora Zakarian | Materials Science | Best Researcher Award

Senior Researcher at Institute for Problems in Materials Science, Ukraine

Dr. Dora Zakarian, a distinguished theorist in solid-state physics, has been contributing to material science since 1980 at the Institute for Problems in Materials Science (IPMS), Ukrainian National Academy of Science, Kyiv, Ukraine. With a doctorate in Physical and Mathematical Sciences, she is renowned for her innovative “a priori pseudopotential” method and groundbreaking studies on the mechanical properties of advanced materials.

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Education 🎓

Dr. Zakarian holds a Doctorate in Physical and Mathematical Sciences, specializing in solid-state physics. Her academic background is rooted in rigorous theoretical approaches, emphasizing quantum mechanics and material modeling.

Professional Experience 💼

Dr. Zakarian’s career spans over four decades at IPMS, where she has conducted theoretical studies of mechanical properties in diverse materials. She developed the “a priori pseudopotential” method, which has led to significant advancements in understanding materials like metals, carbides, borides, and eutectic composites. Her work has influenced fields such as nanotechnology and high-entropy alloys, resulting in dozens of foundational methodologies.

Research Interests 🔬

Dr. Zakarian’s research is centered on computational materials science, particularly:

  • Mechanical properties of composite materials under varying conditions.
  • Thermodynamic modeling of binary systems and eutectics.
  • Pioneering methods to account for size factors, anharmonic effects, and intercomponent interactions in composite materials.
  • Young’s modulus and other critical properties of advanced materials.

Awards and Recognitions 🏆

Dr. Zakarian has actively contributed to international research through:

  1. U.S. Navy Grant (2007-2009) – Simulation of ceramic composites in LaB₆-MeB₂ systems.
  2. U.S. Air Force Grant (2012-2014) – Modeling of boride ceramic composites.
  3. NATO Project Grant (2016-2023) – Development of shock-resistant boron-based ceramics, integrating production and testing.

Her groundbreaking contributions have been recognized globally, with applications in defense and aerospace industries.

Key Publications 📚

Dr. Zakarian has authored numerous peer-reviewed articles. Key works include:

Universal temperature dependence of Young’s modulus

  • Year: 2019
  • Citations: 42

Calculation of composition in LaB6–TiB2 and LaB6–ZrB2 eutectics by means of pseudopotential method

  • Year: 2011
  • Citations: 23

Pseudopotential method for calculating the eutectic temperature and concentration of the components of the B4C–TiB2, TiB2–SiC, and B4C–SiC systems

  • Year: 2009
  • Citations: 19

Ab-initio calculation of the coefficients of thermal expansion for MeB2 (Me–Ti, Zr) and LaB6 borides and LaB6–MeB2 eutectic composites

  • Year: 2012
  • Citations: 11

Quasi-harmonic approximation model in the theory of pseudopotentials

  • Year: 2016
  • Citations: 7

Расчет теоретической прочности алмазоподобных материалов, исходя из энергии взаимодействия атомных плоскостей

  • Year: 2006
  • Citations: 7

Mechanical characteristics of quasibinary eutectic composites with regard for the influence of an intercomponent interaction of the interface

  • Year: 2014
  • Citations: 5

Theoretical Strength of Borides and Quasibinary Boride Eutectics at High Temperatures

  • Year: 2015
  • Citations: 4

Наночастицы с алмазоподобной структурой и обратный закон Холла–Петча

  • Year: 2014
  • Citations: 3

Temperature dependence of the hardness of materials with a metallic, covalent-metallic bonds

  • Year: 2021
  • Citations: 2

For a complete list of publications, please refer to the accompanying document.

Conclusion 🌟

Dr. Dora Zakarian’s contributions to theoretical solid-state physics and materials science are pivotal in advancing our understanding of composite materials. Her innovations in computational methods and models have reshaped the study of mechanical and thermodynamic properties of advanced materials, making her a prominent figure in her field