卞華康

卞華康

於2015年9月博上畢業於金屬材料研究所(日本東北大學),導師為日本電子束3D列印知名專家千葉晶度教授,並於2019年起擔任金屬材料研究所助理教授,2022年7月回到上海大學材料基因組工程研究院擔任教授職務.

長期從事先進合金的微觀組織設計及分析、金屬增材製造(3D列印)工藝與原理研究工作。在鎳鑽基高溫合金、鐵鋁合金以及電子束增材製造鋁合金、欽合金等領域取得了一定學術創新成果。已在研究領域發表具有影響力的SCI論文50餘篇,其中以第一及通訊作者發麥NPG Asia Materials,Additive Manufacturing、 Journal of Materials Science & Technoloqy、 Materials &Design等共20餘篇。申請日本專利2項,其中授權發明專利1項(6485692)。申請並主持國家青年基金項目2項。參與並完成日本政府主導的JST、TRAFAM、NEDO等大型研究項目以及與日本知名企業(豐田汽車、三菱重工、JEOL、日立製作所等)聯合研究項目10餘項。

研究方向,主要成就,獲獎記錄,社會任職,

研究方向

1.先進金屬材料設計與開發
2.基於材料基因工程理念的金屬增材製造製備工藝參數開發與最佳化
3.增材製造製備過程數值模擬技術開發

主要成就

1. Regulating the coarsening of the γ′ phase in superalloys, NPG Asia Materials, 2015, 7, e212.
2. Microstructure refinement for superior ductility of Al–Si alloy by electron beam melting, Additive Manufacturing, 2020, 32, 100982.
3. The microstructure and mechanical properties of selective electron beam melting manufactured 9–12Cr ferritic/martensitic steel using N-and Ar-atomized powder, Additive Manufacturing, 2021 45, 102075.
4. Ball-milling treatment of gas-atomized Ti‒48Al‒2Cr‒2Nb powder and its effect on preventing smoking during electron beam powder bed fusion building process, Additive Manufacturing, 2021, 51, 102634.
5. Spreading behavior of Ti‒48Al‒2Cr‒2Nb powders in powder bed fusion additive manufacturing process: experimental and discrete element method study, Additive Manufacturing, 2021, 102489.
6. Precipitation behavior of a novel cobalt-based superalloy subjected to prior plastic deformations, Materials & Design, 2016, 112, 1-10.
7. The influence of Mo on Suzuki-segregation-related microstructure evolution and mechanical properties of Co−Ni-based superalloy, Journal of Alloys and Compounds, 2018, 768, 136-142.
8. Effect of mechanical ball milling on the electrical and powder bed properties of gas-atomized Ti–48Al–2Cr–2Nb and elucidation of the smoke mechanism in the powder bed fusion electron beam melting process Journal of Materials Science & Technology, 2022, 137, 35-55.
9. Non-equilibrium solidification behavior with solute trapping associated with powder characteristics during electron beam additive manufacturing, Materials & Design, 2022, 221, 110915.
10. Coupled strengthening in HfMoNbTaTi refractory high-entropy alloy via disordered nanoscale phase and semicoherent refractory particle, Materials & Design, 2021, 212, 110248.
11. Hot workability and dynamic recrystallization behavior of a spray formed 7055 aluminum alloy, Materials Characterization, 2021, 178, 111203.
12. Effect of multi-stage heat treatment on mechanical properties and microstructure transformation of Ti–48Al–2Cr–2Nb alloy, Materials Science and Engineering: A, 2021, 816, 141321.
13. Deformation behavior of Mg–5Y–2Nd–05 Zr alloys with different Sm additions, Journal of Alloys and Compounds, 2021, 856, 158201.
14. Fabricating 9–12 Cr ferritic/martensitic steels using selective electron beam melting, Materials Letters, 2020, 271, 127747.
15. Hot deformation characteristics and dynamic recrystallization mechanisms of a Co–Ni-based superalloy, Materials Science and Engineering: A, 2020, 788, 139638.
16. Effects of the aluminum concentration on twin boundary motion in pre-strained magnesium alloys, Journal of Materials Science & Technology, 2020, 73, 116-127.
17. Impacts of pre-strain on twin boundary mobility of magnesium, Journal of Alloys and Compounds, 2020, 816, 152496.
18. Microstructure evolution and mechanical property of a precipitation-strengthened refractory high-entropy alloy HfNbTaTiZr, Materials Letters, 2019, 254, 46-49.
19. High Temperature Deformation Characteristics of an Alumina‐Forming Stainless Steel, steel research international, 2019, 90, 1-12.
20. Competition between solid solution and multi-component Laves phase in a dual-phase refractory high-entropy alloy CrHfNbTaTi, Materials & Design, 2022, 226, 111646.

獲獎記錄

申請並主持國家青年基金項目2項。參與並完成了日本政府主導的JST、TRAFAM、NEDO等大型研究項目以及與日本知名企業(豐田汽車、三菱重工、JEOL、日立製作所等)聯合研究項目10餘項。

社會任職

上海大學材料基因組工程研究院擔任教授職務

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