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分类:导师信息 来源:武汉理工大学材料科学与工程学院 2019-06-25 相关院校:武汉理工大学
研究生导师简介
姓 名
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王为民
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性 别
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男
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民 族
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汉
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出生年月
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1966-02-13
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职 称
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教授
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职 务
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联系电话
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单位名称
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武汉理工大学材料复合新技术国家重点实验室
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Email
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shswmwang@whut.edu.cn
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实验室网址
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研究方向
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先进陶瓷复合材料、材料加工制备新技术、多功能陶瓷复合材料
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教育背景
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1988年7月毕业于武汉工业大学无机材料专业获得工学学士学位;
1991年2月毕业于武汉工业大学无机材料专业,获得工学硕士学位;
1998年10月在武汉工业大学获工学博士学位;
2000年2月至2001年5月在荷兰Delft理工大学从事博士后工作
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工作经历
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1991.04-- 1995.10:武汉工业大学材料复合新技术国家重点实验室、1995.11-- 1998.09:武汉工业大学材料复合新技术国家重点实验室、副研究员
1998.10-- 今:武汉理工大学,材料加工工程学科责任教授、教授,博士生导师,
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项目情况
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1、具有壳核结构的硼化物基可加工陶瓷的制备及界面研究,国家自然科学基金项目,
2、碳--氮化硼层状复合材料的界面设计和制备研究,教育部新世纪人才计划,
3、TiB2可加工陶瓷的界面结构控制研究,教育部博士点基金,
4、高性能抗冲击陶瓷研究与应用,JGXM;
5、改性碳化硼陶瓷的研制与应用,JGXM
6、电场辅助快速成型烧结技术研究,JGXM
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代表性学术
成果 |
获奖成果:
1、自蔓延燃烧合成技术制备TiB2陶瓷粉末技术及其工业应用,建材行业科技进步奖一等奖,1996年,排名第二;
2、自蔓延燃烧合成技术制备TiB2陶瓷粉末技术及其工业应用,国家科技进步三等奖,1997年,排名第二;
3、一种自蔓延高温合成瞬间冲击快速制备金属陶瓷的方法,湖北省技术发明一等奖,2001年,排名第二;
4、反应合成与加工材料基础研究,湖北省自然科学二等奖,2002年,排名第三;
5、复合陶瓷蒸发坩埚研制及产业化,湖北省科技进步奖一等奖,2006年,排名第二;
6、高性能陶瓷蒸发坩埚的低成本制造技术,建材行业技术发明奖一等奖,2008年,排名第二;
7、结构/功能复合化新型导电陶瓷的设计、成套制备技术与应用,国家技术发明二等奖,2012年,排名第二;
部分论文:
1、 Influence of Hot Pressing on Mechanical Properties of TiB2 Ceramics,J. of the Europe ceramics society,Vol.22 p1045-1049,(2002) SCI
2、 Combustion Synthesis Reaction of B2O3-TiO2-Mg,J. of Mate. Proc. Tech,Vol.128,p162-168,(2002) SCI
3、 Manufacture Process of TiB2-Al2O3)/Al composites by Combustion synthesis and Densification, Journal of The Australasian Ceramic Society, Vol38(1)2002, SCI
4、 Microstructure characteristics of BN composites with conductivity ,Journal of Wuhan University of Technology, Vol.17(4)P5-8,(2002) SCI
5、 Phase transformation during joining of an Al-Mg-Li alloy by SPS,Scripta Materialia,2008,
6、 structure and properties of fine-grained alumina fast sintered with high heating rate,2008,
7、 Welding of Ti-6Al-4V and TiB2-Ni cermet using pulsed current heating,Science and Technology of Welding & Joining,2008,
8、 An improved method for chemical bath deposition of ZnS thin films,Chemical Physics Letters, 462(1-3), p84,2008/9/1 SCI,
9、 Thermal Conductivity of Hot Pressing Sintering AlN-BN Composites,Ceramics International,2009,
10、 Fabrication, characterization and photocatalytic activity of La-doped ZnO nanowires,Journal of Alloys and Compounds, 484(1-2), p410,2009/9/18,SCI
11、 Synthesis, characterization and luminescence properties of Y-doped and Tb-doped ZnO nanocrystals,,Materials Science and Engineering B, 162(3), p179,2009/6/15,SCI,
12、 Synthesis, Characterization, and Photocatalytic Activity of Zn-Doped SnO2 Hierarchical Architectures Assembled by Nanocones,Journal of Physical Chemistry C, 113(21), p9071, 2009/5/28, SCI,
13、 Solvothermal synthesis, nanocrystal print and photoelectrochemical properties of CuInS2 thin film,Materials Letters, 64(2),p195-198, 2010/1/31,SCI,
14、 Nest-like structures of Sr doped Bi2WO6: synthesis and enhanced photocatalytic properties,Materials Science and Engineering B 176 (2011) 1264– 1270,SCI
15、 Hydrothermal Synthesis of Hierarchical Rose-like Bi2WO6 Microspheres with High Photocatalytic Activities Under Visible-light Irradiation,Materials Science and Engineering B 177 (2012) SCI
16、 Low temperature synthesis of polycrystalline explosion phase boron nitride submicron-powders.Diamond & Related Materials, 2013, 31, 15-18.
17、 Synthesis of nano-sized amorphous boron powders through active dilution self-propagating high-temperature synthesis method. Materials Research Bulletin, 2013, 48, 2018-2022.
18、 Growth and Optical Properties of Explosion Phase Boron Nitride Octahedron Crystals.Crystal Growth &Design, 2013, 13, 599-605.
19、 Preparation of B4C–SiC composite ceramics through hot pressing assisted bymechanical alloying. International Journal of Refractory Metals and Hard Materials, 2013,41, 270-275.
20、 Morphology Controlled Synthesis and Characterization of Bi2WO6Photocatalysts.Journal of Wuhan University of Technology-Mater. Sci. Ed.28 (2013):231-234.
21、 The Microstructure and properties of B4C-SiC composites prepared by polycarbosilane-coating/B4C powder route,Journal of the European Ceramic Society,34 (2014) 1123–1129
22、 Microstructures and mechanical properties of B4C–SiC intergranular/intragranular nanocomposite ceramics fabricated from B4C, Si, and graphite powders,Journal of the European Ceramic Society 34 (2014) 2153–2161,
23、 Synthesis and structural evolution of B4C–SiC nanocomposite powders by mechanochemical processing and subsequent heat treatment,Powder Technology 254 (2014) P131–136,
24、 Effects of TiB2 on microstructure of nano-gained Cu-Cr-TiB2 composite powders prepared by mechanical allying. Advanced Powder Technology,Vol25 (2014) P415–422
25、 Solvothermal synthesis and electrochemical performance of rod-like V6O13 as cathode material for lithium ion battery,J Electroceram,2014
26、 Solvothermal synthesis and electrochemical performance of Ag-doped V6O13 as cathode material for lithium-ion battery,Ionics,2014
27、 Growth mechanism and ultraviolet-visible property of novel thick-walled boron nitride nanostructures,CrystEngComm,2014, 16,2746-2753,
28、 Mechanical properties and densification of short carbon fiber-reinforced TiB2/C composites produced by hot pressing,Journal of Alloys and Compounds 584 (2014) 87–92
部分专利:
1, 一种制备TiB2-Cf-碳复合材料的方法,ZL2012 1 0002022.2,
2, 一种定向生长八面体爆炸相氮化硼多晶粉末的制备方法,ZL2012 1 0357494.X
3, 一种二硼化钛—氮化钛纳米异质结构复合粉末及其制造方法,ZL2012 1 0381199.8,
4, 一种碳化硼碳化硅复合陶瓷及其制备方法,Zl201210560943.0
5, 一种空心立方结构锌掺杂氧化锡的水热合成方法,
6, 国防专利,200822ZL01,ZL200810074532.4
7, 国防专利,200822ZL06,ZL200810075366.X
8, 国防专利,200822ZL03,ZL200810075200.8
9, 国防专利,200822ZL05,ZL200810076349.8
10, 快速制备碳化锆陶瓷粉体的方法,ZL201010199503.8
11, 半透明Ca*离子掺杂SiAION复相陶瓷材料的制备方法及其产品,ZL2011101783,
12, 半透明Li-α-SiAlON陶瓷材料的快速制备方法,ZL201010181283.6,
13, 一种二硼化锆陶瓷粉末的制备方法,ZL200910060850.X,
14, LiAION透明陶瓷的无压烧结制备方法,ZL201110194521.1
15, 镁热燃烧还原合成碳化锆粉末的方法,ZL200810196896.X
16, 一种提纯碳化锆粉末的方法,ZL201010101112.8,
17, 一种制备碳纳米管增强陶瓷的超快烧结方法,ZL200910060613.3
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