魏大庆

基本信息 科学研究 教育教学 论文专著 发表文章 新建主栏目 基本信息 名称 魏大庆，男，汉族，1979年生。教授；哈尔滨工业大学分析测试与计算中心。 先后主持及参与国家、省部级项目11项，负责承担国家973子课题1项；主持国家自然科学基金1项，参与4项；主持教育部新教师博士点基金1项；主持国家及省博士后基金3项，其中1项为国家博士后特别资助；主持校科研创新基金1项； 获黑龙江省自然科学二等奖（3）；哈尔滨工业大学第五届青年教师研究课程教学竞赛，二等奖；中国硅酸盐学会，建筑材料科学技术奖，一等奖（3）；获国家教材建设一等奖（3）。 在Chemical Engineering Journal（IF=13.2），Bioactive materials(IF=14.5)、ACS Applied Materials & Interfaces(IF=9.2)、Acta biomaterialia(IF=8.9)等国际著名权威杂志上发表学术论文70余篇，合作研究发表于Biomaterials（IF=12.4）, ACTA Materialia, Biosensors and Bioelectronics 等国际著名权威杂志上。H因子24。他引1600次。 1.主编实验教材《电子显微分析分析实验指导》，10万字。 2.出版专著一部，《钛表面微弧氧化生物活性涂层及药物释放》18万字。 参编国家级教材《材料分析方法》的部分章节，撰写13万字。由机械工业出版社出版。 3.受邀撰写英文书籍《Biomimetic based applications》的第九章，撰写3万字，由Intech出版社出版。 荣誉称号 名称 2012年度全省科技创新创业共享服务先进个人； 2011年黑龙江省自然科学二等奖；轻金属表面微弧放电生产特种陶瓷功能复合陶瓷涂层的机理与性能； 2018年中国硅酸盐学会建筑材料科学技术一等奖；微弧诱导功能陶瓷涂层的可控生长及其使役性能研究； 哈尔滨工业大学第五届青年教师研究课程教学竞赛，二等奖 ； 工作经历 名称 2009.03-2012.03、哈尔滨工业大学、博士后 2008.12-2013.12、哈尔滨工业大学、助理研究员 2013.12-2020.12、哈尔滨工业大学、副研究员 2020.12-至今、 哈尔滨工业大学、教授 教育经历 名称 1998.09-2002.07 哈尔滨工业大学 材料成型与控制 学士 2002.09-2004.07 哈尔滨工业大学 材料学 硕士 2004.09-2008.10 哈尔滨工业大学 材料学 博士 2009.03-2012.03 哈尔滨工业大学 化学工程与技术 博士后 主要任职 名称 哈尔滨工业大学分析测试与计算中心副主任； 哈尔滨工业大学分析测试与计算中心电镜平台主任； 黑龙江省电子显微镜学会理事长； 中国CSTM FC98科学试验领域委员会——科学试验创新方法技术委员会委员 中国电子显微镜学会FIB专业委员会委员； 中国生物材料学会医用金属材料分会青年委员会委员； 哈尔滨工业大学材料科学与工程学院青年科技协会 副主席； 中国材料学会会员； 研究领域 名称 主要从事钛及钛合金表面微弧氧化涂层/薄膜的设计及后续加工、生成机理以及生物活性研究。从事大型科研设备——扫描电子显微镜、聚焦离子-电子双束电镜(FIB)的操作工作。 发表文章 1.Meng QC*, Wei DQ, Jia DCC. Mechanical and wear properties of h-BN/Si3N4 ceramic composites. Rare Metal Materials and Engineering 2005;34:558-61. 2.Wei DQ, Meng Q*, Jia DC. Mechanical and tribological properties of hot-pressed h-BN/Si3N4 ceramic composites. Ceramics International 2006;32:549-54. 3.Wei DQ, Meng Q*, Jia DC. Microstructure of hot-pressed h-BN/Si3N4 ceramic composites with Y2O3-Al2O3 sintering additive. Ceramics International 2007;33:221-6. 4.Wei DQ, Zhou Y*, Ha D, Wang YM. Effect of applied voltage on the structure of microarc oxidized TiO2-based bioceramic films. Materials Chemistry and Physics 2007;104:177-82. 5.Wei DQ, Zhou Y*, Jia DC, Wang YM. Structure of calcium titanate/titania bioceramic composite coatings on titanium alloy and apatite deposition on their surfaces in a simulated body fluid. Surf Coat Tech 2007;201:8715-22. 6.Wei DQ, Zhou Y*, Jia DC, Wang YM. Effect of heat treatment on the structure and in vitro bioactivity of microarc-oxidized (MAO) titania coatings containing Ca and P ions. Surf Coat Tech 2007;201:8723-9. 7.Wei DQ, Zhou Y*, Jia DC, Wang YM. Characteristic and in vitro bioactivity of a microarc-oxidized TiO2-based coating after chemical treatment. Acta Biomaterialia 2007;3:817-27. 8.Wei DQ, Zhou Y*, Wang YM, Jia DC. Characteristic of microarc oxidized coatings on titanium alloy formed in electrolytes containing chelate complex and nano-HA. Applied Surface Science 2007;253:5045-50. 9.Wei DQ, Zhou Y*, Jia DC, Wang YM. Influence of applied voltage on the structure of micro-plasma oxidized titania-based coatings formed in an electrolyte containing nano-HA and calcium salts and phosphate. In: Pan W, Gong JH, editors. High-Performance Ceramics V, Pts 1 and 22008. p. 1209-11. 10.Wei DQ, Zhou Y*, Jia DC, Wang YM. Chemical treatment of TiO2-based coatings formed by plasma electrolytic oxidation in electrolyte containing nano-HA, calcium salts and phosphates for biomedical applications. Applied Surface Science 2008;254:1775-82. 11.Wei DQ, Zhou Y*, Jia DC, Wang YM. Formation of CaTiO3/TiO2 composite coating on titanium alloy for biomedical applications. Journal of Biomedical Materials Research Part B-Applied Biomaterials 2008;84B:444-51. 12.Wei DQ, Zhou Y, Jia DC, Wang YM. Biomimetic apatite deposited on microarc oxidized anatase-based ceramic coating. Ceramics International 2008;34:1139-44. 13.Wei DQ, Zhou Y*, Wang YM, Jia DC. Microarc Oxidation of Titanium Alloy to Ca- and P-Containing Gradient Biocoatings. Rare Metal Materials and Engineering 2008;37:569-72. 14.Wei DQ, Zhou Y*, Wang YM, Jia DC. Chemical etching of micro-plasma oxidized titania film on titanium alloy and apatite deposited on the surface of modified titania film in vitro. Thin Solid Films 2008;516:1818-25. 15.Wei DQ, Zhou Y*, Wang YM, Jia DC. Effect of dehydration on structure and induction capability for apatite formation of microarc oxidized TiO2-based film with chemical modification. Thin Solid Films 2008;516:6413-20. 16.Wei DQ, Zhou Y*, Wang YM, Meng Q, Jia DC. Structure and apatite formation of microarc oxidized TiO2-based films before and after alkali-treatment by various alkali concentrations. Surf Coat Tech 2008;202:5012-9. 17.Wei DQ*, Zhou Y. Characteristic and biocompatibility of the TiO2-based coatings containing amorphous calcium phosphate before and after heat treatment. Applied Surface Science 2009;255:6232-9. 18.Wei DQ*, Zhou Y. Preparation, biomimetic apatite induction and osteoblast proliferation test of TiO2-based coatings containing P with a graded structure. Ceramics International 2009;35:2343-50. 19.Wei DQ*, Zhou Y, Yang CH. Characteristic and microstructure of the microarc oxidized TiO2-based film containing P before and after chemical- and heat treatment. Applied Surface Science 2009;255:7851-7. 20.Wei DQ*, Zhou Y, Yang CH. Characteristic, cell response and apatite-induction ability of microarc oxidized TiO2-based coating containing P on Ti6Al4V before and after chemical-treatment and dehydration. Ceramics International 2009;35:2545-54. 21.Wei DQ*, Zhou Y, Yang CH. The composite films of gradient TiO2-based/nano-scale hydrophilic sodium titanate: Biomimetic apatite induction and cell response. Surf Coat Tech 2009;204:372-9. 22.Wei DQ*, Zhou Y, Yang CH. Structure, cell response and biomimetic apatite induction of gradient TiO2-based/nano-scale hydrophilic amorphous titanium oxide containing Ca composite coatings before and after crystallization. Colloids and Surfaces B-Biointerfaces 2009;74:230-7. 23.Cheng S, Wei DQ*, Zhou Y. Mechanical and corrosion resistance of hydrophilic sphene/titania composite coatings on titanium and deposition and release of cefazolin sodium/chitosan films. Applied Surface Science 2011;257:2657-64. 24.Cheng S, Wei DQ*, Zhou Y. Formation and structure of sphene/titania composite coatings on titanium formed by a hybrid technique of microarc oxidation and heat-treatment. Applied Surface Science 2011;257:3404-11. 25.Cheng S, Wei DQ*, Zhou Y. Structure of microarc oxidized coatings containing Si, Ca and Na on titanium and deposition of cefazolin sodium/chitosan composite film. Surf Coat Tech 2011;205:3798-804. 26.Cheng S, Wei DQ*, Zhou Y, Guo HF. Characterization and properties of microarc oxidized coatings containing Si, Ca and Na on titanium. Ceramics International 2011;37:1761-8. 27.Cheng S, Wei DQ*, Zhou Y, Guo HF. Preparation, cell response and apatite-forming ability of microarc oxidized coatings containing Si, Ca and Na on titanium. Ceramics International 2011;37:2505-12. 28.Yang Q, Zhou X, Wei DQ, Cheng S. The index of microarc arc oxidation titnaium substrate including silicon and calcium coatings attribute and the X-ray and biomechanical stability studies after implants in the rabbit shinbone. Journal of oral science research, 2012(28):534-536 29.Feng W, Wei DQ*, Wang HY, Cheng S, Zhou Y. The bioactive nanostructure of microarc-oxidized TiO2-based coating after chemical treatment. China science and technology papers online.2013.http://www.paper.edu.cn 30.Feng W, Wei DQ*, Wang HY, Cheng S, Zhou Y. Apatite formation and drug release ability of nano-sturcture modified bioactive TiO2 based microarc oxidation coatings. China science and technology papers online.2013.http://www.paper.edu.cn 31.Cui W, Wang C, Yan J, Wang Z, Wei DQ. Wetting and reaction promoted by ultrasound between sapphire and liquid Al-12Si alloy. Ultrasonics Sonochemistry 2013;20:196-201. 32.Gao Y, Li BQ, Jia DC, Feng Y, Wei DQ, Zhou Y. Novel lamellar chitosan drug carrier for long-term sustained release: Drug-loading combined with biomineralization. Journal of Controlled Release 2013;172:E87-E. 33.Wang YM, Li BQ, Zhou Y, Han Z, Feng Y, Wei DQ. A facile concentric-layered magnetic chitosan hydrogel with magnetic field remote stimulated drug release. Journal of Controlled Release 2013;172:E90-E. 34.Wang YM, Guo JW, Shao ZK, Zhuang JP, Jin MS, Wu CJ, et al. A metasilicate-based ceramic coating formed on magnesium alloy by microarc oxidation and its corrosion in simulated body fluid. Surf Coat Tech 2013;219:8-14. 35.Wei DQ*, Zhou R, Cheng S, Feng W, Li BQ, Wang YM, et al. Microarc oxidized TiO2 based ceramic coatings combined with cefazolin sodium/chitosan composited drug film on porous titanium for biomedical applications. Materials Science & Engineering C-Materials for Biological Applications 2013;33:4118-25. 36.Zhou R, Wei DQ*, Cheng S, Zhou Y, Jia DC, Wang YM, et al. The effect of titanium bead diameter of porous titanium on the formation of micro-arc oxidized TiO2-based coatings containing Si and Ca. Ceramics International 2013;39:5725-32. 37.Bai YX, Jiao XH, Wei DQ, Zhou Y. Bioactive Sphene/Titanium Oxide Composite Coatings on Titanium: Structure and Apatite Formation Mechanism. Chinese Journal of Inorganic Chemistry 2014;30:1701-11. 38.Wang YM, GuoJW, Zhuang JP, Jing YB, Shao ZK, Jin S, et al. Development and characterization of MAO bioactive ceramic coating grown on micro-patterned Ti6Al4V alloy surface. Applied Surface Science 2014;299:58-65. 39.Wei DQ*, Zhou R, Cheng S, Feng W, Yang HY, Du Q, et al. MC3T3-E1 cells@#% response and osseointegration of bioactive sphene-titanium oxide composite coatings fabricated by a hybrid technique of microarc oxidation and heat treatment on titanium. Journal of Materials Chemistry B 2014;2:2993-3008. 40.Zhou R, Wei DQ*, Cheng S, Feng W, Du Q, Yang HY, et al. Structure, MC3T3-E1 Cell Response, and Osseointegration of Macroporous Titanium Implants Covered by a Bioactive Microarc Oxidation Coating with Microporous Structure. Acs Applied Materials & Interfaces 2014;6:4797-811. 41.Zhou R, Wei DQ*, Cheng S, Li BQ, Wang YM, Jia DC, et al. The structure and in vitro apatite formation ability of porous titanium covered bioactive microarc oxidized TiO2-based coatings containing Si, Na and Ca. Ceramics International 2014;40:501-9. 42.Zhou R, Wei DQ*, Feng W, Cheng S, Yang HY, Li BQ, et al. Bioactive coating with hierarchical double porous structure on titanium surface formed by two-step microarc oxidation treatment. Surf Coat Tech 2014;252:148-56. 43.Zhou R, Wei DQ*, Yang HY, Cheng S, Feng W, Li BQ, et al. Osseointegration of bioactive microarc oxidized amorphous phase/TiO2 nanocrystals composited coatings on titanium after implantation into rabbit tibia. Journal of Materials Science-Materials in Medicine 2014;25:1307-18. 44.Zhou R, Wei DQ*, Yang HY, Feng W, Cheng S, Li BQ, et al. MC3T3-E1 cell response of amorphous phase/TiO2 nanocrystal composite coating prepared by microarc oxidation on titanium. Materials Science & Engineering C-Materials for Biological Applications 2014;39:186-95. 45.Guo JW, Sun SY, Wang YM, Zhou Y, Wei DQ, Jia DC. Hydrothermal biomimetic modification of microarc oxidized magnesium alloy for enhanced corrosion resistance and deposition behaviors in SBF. Surf Coat Tech 2015;269:183-90. 46.Jing SD, Cheng S, Zhou R, Wei DQ, Zhou Y. Structure, Bioactivity and MC3T3-E1 Cell Response of Sodium Hydrogen Titanium Oxide Nanowire on Titanium. Chinese Journal of Inorganic Chemistry 2015;31:824-38. 47.Li BQ, Wang L, Guo J, Xu F, Wei DQ, Feng Y, et al. Cell laden and patterned chitosan microgel for micro-scale tissue engineering. Journal of Controlled Release 2015;213:E9-E. 48.Li BQ, Wang L, Xu F, Gang X, Demirci U, Wei DQ, et al. Hydrosoluble,UV-crosslinkable and injectable chitosan for patterned cell-laden microgel and rapid transdermal curing hydrogel in vivo. Acta Biomaterialia 2015;22:59-69. 49.Zhou R, Wei DQ*, Cao JY, Feng W, Cheng S, Du Q, et al. Conformal coating containing Ca, P, Si and Na with double-level porous surface structure on titanium formed by a three-step microarc oxidation. Rsc Advances 2015;5:28908-20. 50.Zhou R, Wei DQ*, Cao J, Feng W, Cheng S, Du Q, et al. The effect of NaOH concentration on the steam-hydrothermally treated bioactive microarc oxidation coatings containing Ca, P, Si and Na on pure Ti surface. Materials Science & Engineering C-Materials for Biological Applications 2015;49:669-80. 51.Zhou R, Wei DQ*, Cao J, Feng W, Cheng S, Du Q, et al. Synergistic Effects of Surface Chemistry and Topologic Structure from Modified Microarc Oxidation Coatings on Ti Implants for Improving Osseointegration. Acs Applied Materials & Interfaces 2015;7:8932-41. 52.Zhou R, Wei DQ*, Ke H, Cao J, Li BQ, Cheng S, et al. H2Ti5O11.H2O nanorod arrays formed on a Ti surface via a hybrid technique of microarc oxidation and chemical treatment. Crystengcomm 2015;17:2705-17. 53.Wei DQ*, Feng W, Du Q, Zhou R, Li BQ, Wang YM, Zhou Y. Titania nanotube/nano-brushite composited bioactive coating with micro/nanotopography on titanium formed by anodic oxidation and hydrothermal treatment. Ceramics International 2015;41 (10), 13115-13125 申请专利 1.魏大庆，冯唯，周睿，成夙，周玉. 钛表面多级孔结构制备方法. 201310303052.1 2.魏大庆，成夙，周玉.一种纯钛或钛合金表面制备含榍石陶瓷涂层的方法：中国，2010105942330. 3.魏大庆，成夙，周玉.一种纯钛或钛合金表面制备具有生物活性陶瓷涂层的方法：中国，2010105942330. 4.魏大庆，成夙，周玉.一种多孔钛表面制备含榍石生物活性陶瓷涂层的方法：中国，2010105962226 5.魏大庆，成夙，周玉.一种多孔钛表面制备具有生物活性陶瓷涂层的方法：中国，2010105962264 6.魏大庆，成夙，周玉.含纳米晶粒高生物活性二氧化钛涂层的制备方法：中国，201210002155.X 7.魏大庆，成夙，周玉.微弧氧化钛种植体上载头孢唑啉钠药物膜的方法：中国，201210002144.1 8.魏大庆，成夙，周玉.微弧氧化钛种植体上载头孢唑啉钠与壳聚糖复合药物膜的方法：中国，201210002134.8 9.魏大庆，成夙，周玉.医用钛金属表面制备羟基磷灰石及多孔二氧化钛复合涂层的方法：中国，201210002123.X 10.魏大庆，周睿，成夙，周玉.三步法制备双级孔隙微弧氧化陶瓷涂层的方法.201310033724.1 11.魏大庆，周睿，成夙，周玉.一种具有抑菌作用的双级孔微弧氧化生物涂层的制备方法.201310033809.X 12.魏大庆，周睿，成夙，周玉.二步法制备具有宏观多孔微弧氧化涂层的方法.201310034007.0 13.魏大庆，周睿，成夙，周玉.一种钛表面疏水微弧氧化生物涂层的制备方法.201310034010.2 14.魏大庆，周睿，成夙，周玉.含硅、钙、磷、钠微弧氧化涂层的牙根种植基体及其制备方法. 201310034008.5 15.魏大庆，周睿，冯唯，成夙，周玉. 微弧氧化氩气热处理钛表面的制备含榍石生物活性涂层的方法. 201310308816.6 16.魏大庆，周睿，冯唯，成夙，周玉. 钛表面微弧氧化/水汽处理生物活性复合涂层的方法. 201310302998.6 17.魏大庆，周睿，冯唯，成夙，周玉. 钛表面微弧氧化生物活性涂层的碱液水汽后处理方法. 201310302918.7 18.魏大庆，周睿，冯唯，成夙，周玉. 医用钛表面两步法制备宏观/微观双级孔隙结构生物活性微弧氧化陶瓷涂层的方法. 201310303054.0 团队成员 名称 指导本科生7名、硕士生4名。协助指导博士生4名，其中1名博士获校优秀毕业生称号，1名博士获得国家奖学金。 讲授课程 名称 承担4门研究生选修课： 1.《材料分析方法》 2.《电子显微分析技能训练》 3.《材料电子显微分析技术及应用》 4.《材料相变与相结构分析实践》 承担1门本科生选修课： 《材料微纳结构构建及表征》 招生信息 名称 招收硕士研究生：研究方向：金属材料组织结构和性能研究。