姓名:邱剑勋
职称:教授
职务:教师
电话:13863892810
邮箱:[email protected]
办公地点:澳洲幸运10计划
416室
教育背景
1996/09-2000/07,大连工业大学,化工与材料澳洲幸运10计划
,工学学士
2000/09-2003/02,大连工业大学,化工与材料澳洲幸运10计划
,工学硕士
2003/03-2006/02,上海交通大学,材料科学与工程澳洲幸运10计划
,工学博士
工作履历
2006/03-2011/11,烟台大学,澳洲幸运10计划
,讲师
2011/12-2023/12,烟台大学,澳洲幸运10计划
,副教授
2018/06-2021/12,烟台大学,澳洲幸运10计划
,副院长
2022/01-2023/09,烟台大学,教务处,副处长
2024/01-至今,烟台大学,澳洲幸运10计划
,教授
学术兼职
全国大学生金相技能大赛竞赛委员会委员;
山东省大学生金相技能大赛竞赛委员会副主任委员。
研究领域
光催化材料、电磁波吸收材料;
功能薄膜制备与材料表面改性。
科研项目及获奖情况
主持和参与国家自然科学基金、山东省自然科学基金、山东省优秀中青年科学家科研奖励基金、以及企事业单位委托项目等科研项目8项,科研经费二百余万元:
[1]企事业单位委托项目《导电纤维金属化工艺设计及产业化》,主持,2022.03-2025.08;
[2]
山东省优秀中青年科学家科研奖励基金项目《高速切削钛合金服务表面层微观组织结构研究》,主持,2008.01-2010.12;
[3]国家自然科学基金面上项目《金属氮化物纳米复合层的强韧化设计与摩擦学行为研究》,参与(第二位),2022.01-2025.12;
[4]国家自然科学基金青年基金项目《热变形高温钛合金碳化物溶解动力学及其与缺陷的耦合力学行为》,参与(第二位),2010.01-2012.12;
[5]国家自然科学基金青年基金项目《基于空心阴极效应的奥氏体不锈钢表面氮化行为的研究》,参与(第三位),2014.01-2016.12;
[6]山东省自然科学基金项目《航空液压泵关键摩擦副磁场辅助离子源渗氮改性与摩擦学研究》,参与(第二位),2019.01-2021.12;
[7]山东省科技发展计划项目《紧固件用马氏体型高强韧钛合金的高温变形工艺优化》,参与(第三位),2012.07-2015.07;
[8]山东省自然科学基金项目《β钛合金组元协同效应及其强韧化机理的第一原理研究》,参与(第三位),2014.12-2017.12。
获奖情况:
[1]邱剑勋(首位),山东高等学校优秀科研成果三等奖,《铁磁材料吸收电磁波机理研究》,2009.12;
[2]邱剑勋(第三位),山东省科技进步三等奖,《工业室内空气化学污染物选择性吸附净化技术与设备》,2009.01;
[3]邱剑勋(第三位),烟台市科学技术进步三等奖,《新型高功效复合环境净化技术》,2009.10。
代表性学术成果
以首位或通讯作者在国内外学术刊物上发表学术论文20余篇:
[1]Epoxy Resin/(α-Al2O3/ZrO2) Nanocomposite for Antifriction andCorrosion Resistance.ACS Applied Nano Materials.
[2]Simultaneous enhancement of hardness, lubrication and corrosion resistance of solid solution Zr-Y-N film. Surface & Coatings Technology.
[3]Improved seawater corrosion resistance of electron beam melting Ti6Al4V titanium alloy by plasma nitriding. Vacuum.
[4]Characterization and electrochemical behavior of a multilayer-structured Ti–N layer produced by plasma nitriding of electron beam melting TC4 alloy in Hank’s solution. Vacuum.
[5]Tailoring the strengthening-toughening behavior of the MoSi2film by doping trace solute Au. Surface & Coatings Technology.
[6]Preparation mechanism and properties of a ceramic–based interference microwave absorbing composite prepared by a high–temperature foaming method. Materials Chemistry and Physics.
[7]Preparation of high–strength closed–pore foamed ceramics from desalted sea sand at temperatures below 1000℃. Ceramics International.
[8]Effect of titanium dioxide on microwave absorption properties of barium ferrite. Journal of Alloys and Compounds.
[9]Photocatalytic Properties and Optical Absorption of ZnFe2O4Doped TiO2Films. Surface Engineering.
[10]Microwave absorption properties of substituted BaFe12O19/TiO2nanocomposite multilayer film. Journal of Materials Science.
[11]Crystal structure and magnetic properties of BaFe12-xDyxO19powders prepared using self-propagating combustion. Journal of Composite Materials.
[12]Crystal structure and magnetic properties of barium ferrite synthesized using GSPC and HEBM. Journal of Alloys and Compounds.
[13]Effect of Cr substitution on microwave absorption of BaFe12O19. Materials Letters.
[14]Microwave absorption properties of nanocomposite films of BaFe12O19and TiO2prepared by sol-gel method. Materials Science and Engineering B.
[15]Mechanism of increasing the electromagnetic absorption of composites prepared by BaFe12O19and TiO2. Advanced Composites Letters.
[16]Effect of aluminum substitution on microwave absorption properties of barium hexaferrite. Journal of Applied Physics.
[17]Magnetic nanocomposite thin films of BaFe12O19and TiO2prepared by sol-gel method. Applied Surface Science.
[18]Microwave absorption properties of Al- and Cr-substituted M-type barium hexaferrite. Journal of Magnetism and Magnetic Materials.
[19]Microwave absorption of nanosized barium ferrite particles prepared using high-energy ball milling. Powder Technology.
[20]Nanocrystalline structure and magnetic properties of barium ferrite particles prepared via glycine as a fuel. Materials Science and Engineering A.
[21]Photocatalytic properties and optical absorption of zinc ferrite nanometer films. Materials Science and Engineering B.
