共找到94條詞條名為徐偉的結果 展開

徐偉

東北大學教授

徐偉,1979年10月生,東北大學軋制技術及連軋自動化國家重點實驗室(RAL)教授,博士生導師,中組部2014年(青年)引進人才(優先資助)。本科和碩士分別於2002和2005年畢業於中國科學技術大學固體徠與材料力學專業。2009年博士畢業於荷蘭代爾夫特科技大學材料科學與工程專業(cum laude,優秀博士畢業生)。自2009年起歷任安賽羅米塔爾全球研發中心(比利時)研究員、高級研究員,同時雙聘為荷蘭Delft科技大學助理教授。一直從事先進高強鋼的計算設計和產業化開發工作。已主持國家自然科學基金面上項目,歐盟鋼碳聯盟RFCS等項目,共發表SCI/EI收錄論文50餘篇,並榮獲荷蘭皇家科學與人文協會2012年度最佳青年科學家等獎項。

學習工作經歷


學習經歷

1998-2002:中國科學技術大學固體與材料力學專業學士
2002-2005:中國科學技術大學固體與材料力學專業碩士。
2005-2009:荷蘭代爾夫特科技大學材料科學與工程專業 博士(cum laude,優秀博士畢業生,4%)。

工作經歷

2009-2015:安賽羅米塔爾(ArcelorMittal,全球最大鋼鐵企業)全球研發中心研究員、高級研究員。2012年起雙聘為荷蘭Delft科技大學助理教授。一直從事先進高強鋼的計算設計和產業化開發工作,在基礎研究和工程應用中都取得了一系列成果。

主要成就

• 入選第四批國家“萬人計劃”-“科 技創新領軍人才”
• 中組部(青年)引進人才,優先資助, 2014
• William Mong訪問研究學者,香港大學, 2013.
• 2012年度荷蘭皇家科學與社會協會青年科學家獎Martinus van Marum Prize (此獎項為荷蘭皇家科學與社會協會針對青年科學家的最高獎項,針對全部科學與工程學科每年只有一名獲獎者).
• 優秀博士畢業生CUM LAUDE 2009. (4% 獲獎比率).
• 荷蘭金屬所最佳應用價值獎,2009.

主要著作


Publications:

• Xu, X., S. van der Zwaag, and W. Xu,A novel multi-pass dual-indenter scratch test to unravel abrasion damage formation in construction steels.Wear, 2015.322-323: p. 51-60.
• Xu, X., S. van der Zwaag, and W. Xu,Prediction of the abrasion resistance of construction steels on the basis of the subsurface deformation layer in a multi-pass dual-indenter scratch test.Wear, 2015.338-339: p. 47-53.
• Silva, E.P.D., et al.,Isothermal transformations in advanced high strength steels below martensite start temperature.Materials Science and Technology, 2015.31(7): p. 808-816.
• Lu, Q., et al.,The impact of intended service temperature on the optimal composition of Laves and M23C6 precipitate strengthened ferritic creep resistant steels.Computational Materials Science, 2015.107: p. 110-115.
• He, B.B., W. Xu, and M.X. Huang,Effect of ausforming temperature and strain on the bainitic transformation kinetics of a low carbon boron steel.Philosophical Magazine, 2015.95(11): p. 1150-1163.
• Farahani, H., W. Xu, and S. van der Zwaag,Prediction and Validation of the Austenite Phase Fraction upon Intercritical Annealing of Medium Mn Steels.Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science, 2015.46(11): p. 4978-4985.
• De Knijf, D., et al.,In situ austenite–martensite interface mobility study during annealing.Acta Materialia, 2015.90: p. 161-168.
• Pinto Da Silva, E., et al.,Phase transformations during the decomposition of austenite below M s in a low-carbon steel.Materials Characterization, 2014.95: p. 85-93.
• Lu, Q., W. Xu, and S.V.D. Zwaag,Designing new corrosion resistant ferritic heat resistant steel based on optimal solid solution strengthening and minimisation of undesirable microstructural components.Computational Materials Science, 2014.84: p. 198-205.
• Lu, Q., W. Xu, and S. van der Zwaag,A material genomic design of advanced high performance, noncorroding steels forambient and high temperature applications, inMaterials Science Forum. 2014. p. 1201-1206.
• Lu, Q., W. Xu, and S. van der Zwaag,A material genomic design of advanced high performance, noncorroding steels for ambient and high temperature applications, inAdvanced Materials Research. 2014. p. 1201-1206.
• Lu, Q., W. Xu, and S. van der Zwaag,The Computational Design of W and Co-Containing Creep-Resistant Steels with Barely Coarsening Laves Phase and M23C6as the Strengthening Precipitates.Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science, 2014.45(13): p. 6067-6074.
• Lu, Q., W. Xu, and S. Van Der Zwaag,A strain-based computational design of creep-resistant steels.Acta Materialia, 2014.64: p. 133-143.
• Lu, Q., W. Xu, and S. Van Der Zwaag,The design of a compositionally robust martensitic creep-resistant steel with an optimized combination of precipitation hardening and solid-solution strengthening for high-temperature use.Acta Materialia, 2014.77: p. 310-323.
• He, B.B., W. Xu, and M.X. Huang,Increase of martensite start temperature after small deformation of austenite.Materials Science and Engineering: A, 2014.609: p. 141-146.
• Dilner, D., et al.,Process-time optimization of vacuum degassing using a genetic alloy design approach.Materials, 2014.7(12): p. 7997-8011.
• da Silva, E.P., et al.,Combined martensite and bainite formation from austenite decomposition in HSLA steel, inAdvanced Materials Research. 2014. p. 682-687.
• Chen, H., et al.,Predicting the Austenite Fraction After Intercritical Annealing in Lean Steels as a Function of the Initial Microstructure.Metallurgical and Materials Transactions A, 2014.45(4): p. 1675-1679.
• Xu, X., et al.,Design of low hardness abrasion resistant steels.Wear, 2013.301(1-2): p. 89-93.
• Lu, Q., W. Xu, and S. Van Der Zwaag,Computational design of precipitation strengthened austenitic heat-resistant steels.Philosophical Magazine, 2013.93(25): p. 3391-3412.
• Xu, W., et al.,The structure of a general materials genome approach to the design of new steel grades for specific properties.Computer Method in Materials Science, 2012.13(1): p. 382-394.
• Chen, H., et al.,Application of the stagnant stage concept for monitoring Mn partitioning at the austenite-ferrite interface in the intercritical region for Fe-Mn-C alloys.Philosophical Magazine Letters, 2012.92(10): p. 547-555.
• Xu, W. and S. Van Der Zwaag,Property and cost optimisation of novel UHS stainless steels via a genetic alloy design approach.ISIJ International, 2011.51(6): p. 1005-1010.
• Rivera-Diaz-Del-Castillo, P.E.J. and W. Xu,Heat treatment and composition optimization of nanoprecipitation hardened alloys.Materials and Manufacturing Processes, 2011.26(3): p. 375-381.
• Xu, W., et al.,A new ultrahigh-strength stainless steel strengthened by various coexisting nanoprecipitates.Acta Materialia, 2010.58(11): p. 4067-4075.
• Xu, W., et al.,Genetic design and characterization of novel ultra-high-strength stainless steels strengthened by Ni3Ti intermetallic nanoprecipitates.Acta Materialia, 2010.58(10): p. 3582-3593.
• Rivera-Díaz-del-Castillo, P.E.J., W. Xu, and S. Van Der Zwaag,Genetic alloy design of ultra high strength stainless steels: From thermodynamics to quantum mechanics, inMaterials Science Forum. 2010. p. 3473-3478.
• Xu, W., P.E.J. Rivera-Diaz-Del-Castillo, and S. Van Der Zwaag,Computational design of UHS maraging stainless steels incorporating composition as well as austenitisation and ageing temperatures as optimisation parameters.Philosophical Magazine, 2009.89(20): p. 1647-1661.
• Xu, W., P.E.J.R.D.D. Castillo, and S.V.D. Zwaag,The composition and temperature effects on the ultra high strength stainless steel design.International Journal of Modern Physics B, 2009.23(6-7): p. 1060-1065.
• Xu, W., P.E.J.R.D.d. Castillo, and S.v.d. Zwaag,A combined optimization of alloy composition and aging temperature in designing new UHS precipitation hardenable stainless steels.Computational Materials Science, 2009.45(2): p. 467-473.
• Xu, W., P.E.J. Rivera-Díaz-del-Castillo, and S. van der Zwaag,Designing nanoprecipitation strengthened UHS stainless steels combining genetic algorithms and thermodynamics.Computational Materials Science, 2008.44(2): p. 678-689.
• Xu, W., P.E.J. Rivera-Diaz-Del-Castillo, and S. Van Der Zwaag,Genetic alloy design based on thermodynamics and kinetics.Philosophical Magazine, 2008.88(12): p. 1825-1833.
• Xu, W., et al.,Modelling and characterization of chi-phase grain boundary precipitation during aging of Fe-Cr-Ni-Mo stainless steel.Materials Science and Engineering A, 2007.467(1-2): p. 24-32.
• Xu, W., et al.,Modelling Chi-phase precipitation in high molybdenum stainless steels, inAdvanced Materials Research. 2007. p. 531-536.
• Xu, W., P.E.J. Rivera-Díaz-Del-Castillo, and S. Van Der Zwaag,Ferrite/pearlite band prevention in dual phase and TRIP steels: Model development.ISIJ International, 2005.45(3): p. 380-387.
• Rivera-Díaz-Del-Castillo, P.E.J., et al.,Theory for diffusional transformation kinetics: Multicomponent and multiphase systems.Scripta Materialia, 2005.53(9): p. 1089-1094.
• Huang, W., W. Xu, and Y. Xia,Effect of strain rate on the mechanical behaviors of SiC fiber.Journal of Materials Science, 2005.40(2): p. 465-468.

Conference proceedings

• Lu, Q., W. Xu, and S. Van Der Zwaag.A computational design study of novel creep resistant steels for fossil fuel power. inAdvances in Materials Technology for Fossil Power Plants - Proceedings from the 7th International Conference. 2014.
• Da Silva, E.P., et al.MIcrostructural evolution of a low-carbon steel during the austenite decomposition below MS. inMETAL 2014 - 23rd International Conference on Metallurgy and Materials, Conference Proceedings. 2014.
徠• Lu, Q., W. Xu, and S. Van Der Zwaag.Material genomic design of advanced high strength steels. inTHERMEC 13. 2013. Las Vegas, USA.
• Lu, Q., W. Xu, and S. Van Der Zwaag.Model based redesign of MX carbonitrides strengthened austenitic heat resistant steels. inTMS Annual Meeting. 2013.
• Da Silva, E.P., et al.Combined martensite and bainite formation from austenite decomposition in HSLA steel. inThermec 13. 2013. Las vegas, USA.
• Xu, W., et al.Genetic computational design of novel ultra high strength stainless steels: Model description and first experimental validation. inTMS Annual Meeting. 2009.
• Xu, W., P.R.D. Del Castillo, and S. Van Der Zwaag.Using genetic algorithm to design new ultra-high strength stainless steels reinforced by separate precipitate families. in6th European Stainless Steels Conference. 2009. Helsinki, Finland.
• Xu, W., P.E.J.R.D. Del Castillo, and S. Van Der Zwaag.Computational design of UHS stainless steel strengthened by multi-species nanoprecipitates combining genetic algorithms and thermokinetics. inNew Developments on Metallurgy and Applications of High Strength Steels, Buenos Aires 2008 - Proc. Int. Conf. New Developments on Metallurgy and Applications of High Strength Steels. 2008.
• Del Castillo, P.E.J.R.D., W. Xu, and S. Van Der Zwaag.Theory for multicomponent diffusional kinetics and its application to the reaustenitisation of dual phase and TRIP steels. inProceedings of an International Conference on Solid-Solid Phase Transformations in Inorganic Materials 2005. 2005.