Prof. Dr. Lei Wang is a distinguished expert in materials science and engineering, currently serving as Director of the Institute of Advanced Material Technology at Northeastern University, China ποΈπ¬. He earned his Ph.D. from Toyohashi University of Technology, Japan π―π΅ and has over 40 years of teaching and research experience spanning China and Japan ππ. His research focuses on microstructural control, strengthening mechanisms, and high-temperature materials βοΈπ₯. With over 420 publications and 12 books, Prof. Wang is a recognized leader in advanced materials innovation, scientific mentorship, and international academic collaboration π§ͺππ.
Prof. Dr Lei Wang, Northeastern University, China
Profile
SCOPUS
Education π
Prof. Dr. Lei Wang holds a distinguished academic background in Materials Science and Engineering ππ¬. He earned his Ph.D. in Materials System Engineering from Toyohashi University of Technology, Japan (1994β1997) π―π΅, where he specialized in advanced materials research. Prior to that, he completed his M.S. (1983β1986) and B.S. (1978β1982) at Northeastern University in Shenyang, China π¨π³. His academic training laid a robust foundation for his work on high-performance materials, microstructural control, and engineering mechanics, making him a global expert in his field π§ͺποΈ.
Experience ποΈ
Prof. Dr. Lei Wang has over four decades of experience in materials science and engineering π§ͺπ. Since 2001, he has served as a Distinguished Professor at Northeastern University, China, leading research in metal and high-temperature materials π©π₯. He has held academic positions in Japan at Toyohashi University, Tottori University, and Tohoku University, supervising numerous Ph.D. and Master’s students π§βππ. His teaching and research span fracture mechanics, ceramic composites, and biomaterials. With a rich international background and long-standing academic leadership, he has significantly advanced both theoretical knowledge and practical applications in materials engineering across Asia and beyond πποΈ.
Scientific Research π§ͺ
Prof. Dr. Lei Wang focuses his research on the strengthening and toughening of advanced materials through precise microstructural control π¬π§±. He investigates the mechanical behavior of materials under dynamic loading and extreme environmental conditions, which is crucial for aerospace, automotive, and energy applications βοΈπ₯. His work spans metallic alloys, ceramics, and composites, contributing significantly to materials design and performance optimization. With over 420 peer-reviewed papers and 12 published books, he has made a lasting impact on the field of materials science and engineering ππ§ͺ. His innovations support the development of next-generation high-performance materials ππ§.
Leadership π
Prof. Dr. Lei Wang plays a prominent leadership role in the materials science community both nationally and internationally π. He serves as Vice President of the Heat Treatment Society of China and is an Executive Committee Member of the High Temperature Materials Branch under the Chinese Society for Metals and the Materials Branch of the Chinese Society of Mechanical Engineering ποΈβοΈ. He also leads as President of the Heat Treatment Society of Liaoning Province and was named a Taishan Industry Leading Leader in 2018 π
. Additionally, he is a Visiting Professor at Tohoku University, Japan π―π΅π.
Research Focus π¬
Prof. Dr. Lei Wang focuses on the design, strengthening, and microstructural evolution of advanced metallic materials and superalloys π©π₯. His work spans corrosion behavior in sulfur-containing environments π§ͺ, electromagnetic casting of high-performance alloys β‘, hot deformation processes, and microstructure-property relationships under various thermal and mechanical conditions π οΈπ‘οΈ. He also investigates crystal structure engineering, including recrystallization under electric pulse treatment, and the dielectric properties of doped ceramics π¬π. His studies contribute to developing high-performance materials for aerospace, energy, and structural applications, ensuring both durability and functional optimization in extreme environments πποΈ.
Publications π
Influence of hot deformation parameters on the microstructure evolution of low-expansion GH2909 superalloy
Authors: P. Zhang, C. Lan, L. Wang, H. Zhang, H. Zhou
Journal: Materials Characterization π οΈπ
Effects of Solution Temperature on the Microstructural Evolution and Mechanical Properties of the GH4706 Alloy
Authors: C. Wang, L. Wang, S. Huang, H. Qin, B. Zhang
Journal: JOM ππ¬
Dendrite Fragmentation Behavior and Mechanism during the Solidification of GH4742 Superalloy under Permanent Magnetic Stirring
Authors: J. Wang, L. Wang, X. Song, Y. Liu
Journal: Metals and Materials International βοΈπ©
Effect of trivalent acceptor ions size on the dielectric properties of donor-acceptor co-doped TiO2 single crystals
Authors: L. Wang, J. Li, M. Xu, X. Sun
Journal: Ceramics International πΊπ
Preparation and properties of FeβSiβBβCrβC amorphous alloy powders by air-water combination atomization with different particle sizes
Authors: S. LΓΌ, C. Kuang, L. Wang, J. Zhang, R. Cao
Journal: Fenmo Yejin Jishu/Powder Metallurgy Technology βοΈπ¬
An Oriented Recrystallization Nucleation Mechanism of a Cold-Rolled Pure Ti with Electric-Pulse Treatment
Authors: Q. Shi, L. Wang, X. Song, Y. Liu
Journal: Materials π§ͺβ‘
Corrosion mechanism of K411 superalloy in sulfur-containing environment: sulfidation promoting internal nitridation
Authors: R. Yu, Y. Wang, L. Wang, X. Jiang, J. Dong
Journal: Corrosion Reviews π§³βοΈ