Lin Wang

Associate Professor, master tutor, Beijing Institute of Technology. Director of the Branch of Metallography and Microanalysis of Chinese Stereology Society. He is mainly engaged in the research of optimal design, structure-performance characterization and application effectiveness evaluation of high-efficiency damage and high-performance protective materials for extreme environments. He taught the English undergraduate courses "Progress in Materials Science and Engineering" (Beijing Institute of Technology undergraduate "Curriculum Thinking and Politics" demonstration course), "Solid Phase Transformation" and "Alloy Thermodynamics" graduate courses, and won the Outstanding instructor award in the National Metallographic Skills Competition for college students for many times. Presided over/participated in key projects of foundation strengthening, equipment advance research, engineering application, national and equipment key laboratory fund, and inter-enterprise projects. He won the second prize of National Defense Science and Technology Progress Award, published more than 60 papers, authorized 8 invention patents, and participated in the compilation of 1 book.

1. Efficient damage materials: high-strength steel, titanium alloy;
2. High-performance protective materials: titanium alloy, aluminum alloy, composite materials, electronic materials and device protection, etc.;
3. Nanocrystalline and nano-twin materials.

1988.9-1992.7 Harbin Institute of Technology, Metal Materials and Heat Treatment, Bachelor;
1996.9-1999.3 Beijing Institute of Technology, Master of Materials Science;
1999.3-2002.9 Beijing Institute of Technology, PhD in Materials Science.

1992.7-1996.9 China Aerospace Sanjiang Group Co., LTD., Assistant Engineer;
2002.9-2004.7 Lecturer, School of Materials, Beijing Institute of Technology;
2004.7- Now Associate Professor, School of Materials, Beijing Institute of Technology;
2011.1-2012.1 University of Western Ontario and University of Toronto, Visiting scholar.

1. Microstructure and mechanical properties of a novel high-density steel having high tungsten content. Materials Science & Engineering A, 2021，824: 141797
2. Mechanical (compressive) form of driving force triggers the phase transformation from β to ω & α” phases in metastable β phase-field Ti-5553 alloy. Journal of Materials Science & Technology, 2021,78(19): 238-246
3. Microstructures and mechanical properties of FeCoNi(MoW)x high-entropy alloys. Materials Letters, 2021,9,131250
4. Research on dynamic compression properties and deformation mechanism of Ti6321 titanium alloy. Journal of Materials Research and Technology, 2020,9:11509
5. Omega phase formation and deformation mechanism in heat treated Ti-5553 alloy under high strain rate compression. Materials Letters, 2019,236:163-166