1985.09-1989.06：:金属物理专业，学士，东北大学 1989.09-1992.03：材料加工工程专业，工学硕士，东北大学 1997.9-2002.8：材料加工工程专业，工学博士，东北大学

1992.4-1997.12 东北大学金属压力加工系助教、讲师 1998.01-2009.12 东北大学轧制技术及连轧自动化国家重点实验室，讲师、副教授 2010.01-2012.05东北大学轧制技术及连轧自动化国家重点实验室，教授 2012.06-至今东北大学轧制技术及连轧自动化国家重点实验室，教授、博士生导师

主要研究项目 1) 海洋平台用高锰高强韧中厚板及钛/钢复合板研究与生产技术开发，863计划项目 2) 高强度耐腐蚀石油天然气集输和输送用管线钢生产技术，国家科技支撑计划项目 3) 700MPa级高强度集装箱用耐候钢研发，企业合作项目 4) 高强度耐酸性腐蚀钢板基础技术研究，企业合作项目 5) 提高高铁弹簧钢抗氢脆耐腐蚀能力的研究与应用，企业合作项目 6) 高强耐候钢开发，企业合作项目 7) 铁路车辆用高耐蚀性ᠦ୔

专著情况： 1) 国家级九五重点教材，《金属塑性加工学-轧制理论与工艺》，北京：冶金工业出版社，2001 2) 21世纪初高等教育教学改革项目《材料成形机械设备电子教材》，电子工业出版社2003， 3) 普通高等教育“十五”国家级规划教材，材料成形工艺学，北京：冶金工业出版社， 2006 4) 冶金职业技能丛书－钢管生产知识问答，冶金工业出版社， 2007 5) 李群 高秀华《钢管生产》，北京：冶金工业出版社，2008 6) 普通高等教育国家级重点教材《金属塑性加工学-轧制理论与工艺》，第3版 ，北京：冶金工业出版社，2012 7) 普通高等教育“十二五”规划教材，材料成型机械设备，北京：冶金工业出版社，2014 8) 现代轧钢学，北京，冶金工业出版社，2014 。论文情况： 1) Impact of reversed austenite on the impact toughness of the high-strength steel of low carbon medium manganese[J]. JOM, 2018, 70(5): 672-679. 2) Intercritical tempering enables nanoscale austenite/ε-martensite formation in low-C medium-Mn steel: A pathway to control mechanical properties[J]. Materials Science & Engineering A, 2018, 736: 417-430. 3) Effect of tempered martensite and ferrite/bainite on corrosion behavior of low alloy steel used for flexible pipe exposed to high-temperature brine environment[J]. Journal of Materials Engineering and Performance, 2018, 27: 4911-4920. 4) Corrosion mechanism of low-alloy steel used for flexible pipe in vapor-saturated H2S/CO2 and H2S/CO2-saturated brine conditions[J]. Materials and Corrosion, 2018, 69(9): 1180-1195. 5) Comparison of medium manganese steel and Q345 steel on corrosion behavior in a 3.5 wt % NaCl solution[J]. Materials, 2017, 10(8): 938. 6) Offset effect of chromium on the adverse impact of manganese in a low-C medium-Mn steel with reversed austenite in the neutral salt spray condition[J]. Corrosion, 2017, 73(11): 1367-1380. 7) Comparison of corrosion behaviour of low-alloy pipeline steel exposed to H2S/CO2-saturated brine and vapour-saturated H2S/CO2 environments[J]. Electrochimica Acta, 2017, 232: 528-541. 8) Comparison of corrosion behaviors of low-alloy steel exposed to vapor-saturated H2S/CO2 and H2S/CO2-saturated brine environments[J]. Materials and Corrosion, 2017, 68: 566-579. 9) Comparison of corrosion mechanism of low-alloy pipeline steel used for flexible pipes at vapor-saturated CO2 and CO2-saturated brine conditions[J]. Materials and Corrosion, 2017, 68:1200-1211. 10) Corrosion behaviour of low-alloy pipeline steel exposed to H2S/CO2-saturated saline solution[J]. Journal of Materials Engineering and Performance, 2017, 26(3):1010-1017. 11) Relationship between microstructure and hydrogen induced cracking behavior in a low alloy pipeline steel[J]. Journal of Materials Science & Technology, 2017, 33: 1504-1512. 12) Corrosion behavior of low-C medium-Mn steel in simulated marine immersion and splash zone environment[J]. Journal of Materials Engineering and Performance, 2017, 26(6): 2599-2607. 13) Corrosion characteristics of low alloy steel under H2S/CO2 environment: Experimental analysis and theoretical research[J]. Materials Letters, 2017, 209: 459-462. 14) Corrosion behaviour of low-alloy martensite steel exposed to vapour-saturated CO2 and CO2 -saturated brine conditionsElectrochimica Acta ,2016 ,213 :842-855. 15) Development of reduced rolling process for steel plate, Materials Science Forum, 2012, 706-709 : 2101-2106 16) Development of high deformability pipeline steel, Rare Metal Materials and Engineering，2011,40(S3):273-275 17) The calculation of magnetic induction in grain orientated ultra-thin silicon steel sheets, Journal of Materials Science,2007,42(20),8667-8670 18) Magnetic properties of grain oriented ultra-thin silicon steel sheets processed by conventional rolling and cross shear rolling, Materials Science & Engineering A,2006,430:138-141 19) New process of ultra-thin grain oriented silicon steel producing, Rare Metal, 2006,25(S): 454-457 20) Texture characteristics of grain oriented silicon steel sheets produced by cross shear rolling, Journal of Materials Science Technology, 2000,16(2):155-156

专利情况： 1) 一种深海用海洋软管铠装层用钢及其制备方法，中国，ZL201510249014.1 2) 一种取向硅钢极薄带的制造方法，中国，ZL200410021496.7 3) 金属氢渗透性能测定的装置及方法，中国，ZL201010185642.5 4) 一种V-N微合金化Q550级别中厚板及其制备方法，中国，CN201510403905.8 5) 一种低碳中锰高强韧性特厚钢板的制备方法，中国，CN201510353679.7