WANG Pei | |
Title:Professor | Email: pwang@imr.ac.cn |
Tel. : +86-24-83970106 | FAX: +86-24-83970097 |
Division: Shenyang National Laboratory for Materials Science | |
Address: Institute of Metal Research Chinese Academy of Sciences (IMR CAS), 72 Wenhua Road,Shenyang,China, 110016 |
Experience: |
Education: 2005.9-2011.6 Institute of Metal Research, Chinese Academy of Science 2001.9-2005.7 Wuhan University Work Experience: 2011.7-2013.10 Institute of Metal Research, Chinese Academy of Science Assistant Professor 2013.10- Institute of Metal Research, Chinese Academy of Science Associate Professor |
Research Interest: |
Stainless steel, Heat resistant steel and Steel used in Nuclear energy field; Heat treatment of steel |
Research Achievement: |
Service to the International Professional Societies: |
Honors: |
Publication: |
1) Zhang X, Wang P*, Li D*, Li Y. Multi-scale study on the heterogeneous deformation behavior in duplex stainless steel. Journal of Materials Science & Technology 2021;72:180-188. 2) Jiang Z, Wang P*, Li D*, Li Y. Effects of rare earth on microstructure and impact toughness of low alloy Cr-Mo-V steels for hydrogenation reactor vessels. Journal of Materials Science & Technology 2020;45:1-14. 3) Zhou H, Zhang X, Wang P*, Lu S*. Crystal plasticity analysis of cylindrical holes and their effects on the deformation behavior of Ni-based single-crystal superalloys with different secondary orientations. International Journal of Plasticity 2019;119:249-272. 4) Hu G, Wang P*, Li D, Li Y. Effects of nitrogen on precipitation and tensile behaviors of 25Cr 20Ni austenitic stainless steels at elevated temperatures. Materials Science and Engineering: A 2019;752:93-100. 5) Jiang Z, Wang P*, Li D, Li Y. Influence of the decomposition behavior of retained austenite during tempering on the mechanical properties of 2.25Cr-1Mo-0.25?V steel. Materials Science and Engineering: A 2019;742:540-552. 6) Hu G, Wang P*, Li D, Li Y. The tensile behaviors of vanadium-containing 25Cr-20Ni austenitic stainless steel at temperature between 200 °C and 900 °C. Materials Science and Engineering: A 2018;711:543-552. 7) Jiang Z, Wang P*, Li D, Li Y. The evolutions of microstructure and mechanical properties of 2.25Cr-1Mo-0.25V steel with different initial microstructures during tempering. Materials Science and Engineering: A 2017;699:165-175. 8) Dong H, Wang P*, Li D, Li Y. Effect of pre-deformation on the oxidation resistance of a high Si ferritic/martensitic steel in oxygen-saturated stagnant lead-bismuth eutectic at 550 °C. Corrosion Science 2017;118:129-142. 9) Ye Z, Wang P*, Dong H, Li D, Zhang Y, Li Y. Oxidation mechanism of T91 steel in liquid lead-bismuth eutectic: with consideration of internal oxidation. Scientific reports 2016;6:35268. 10) Dong H, Ye Z, Wang P*, Li D, Zhang Y, Li Y. Effect of cold rolling on the oxidation resistance of T91 steel in oxygen-saturated stagnant liquid lead-bismuth eutectic at 450 °C and 550 °C. Journal of Nuclear Materials 2016;476:213-217. 11) Zhang S, Wang P*, Li D, Li Y. Investigation of the evolution of retained austenite in Fe–13%Cr–4%Ni martensitic stainless steel during intercritical tempering. Materials & Design 2015;84:385-394. 12) Zhang S, Wang P*, Li D, Li Y. In situ investigation on the deformation-induced phase transformation of metastable austenite in Fe–13% Cr–4% Ni martensitic stainless steel. Materials Science and Engineering: A 2015;635:129-132. 13) Ye Z, Wang P*, Li D, Li Y. M23C6 precipitates induced inhomogeneous distribution of silicon in the oxide formed on a high-silicon ferritic/martensitic steel. Scripta Materialia 2015;97:45-48. |
Homepage: |