一、 个人基本信息
出生日期: 1982年1月
籍贯: 山东长清
性别: 男
民族: 汉
专业技术职务:教授
最高学历:博士研究生
工作单位:中国民航大学研究生院
通信地址:天津市东丽区津北公路2898号
邮政编码:300300
电 话:15122848807
电子邮箱:twei@cauc.edu.cn
二、学习和工作经历简介
2018.12—至今,中国民航大学,教授
2017.09—2018.09,英国剑桥大学,材料系,访问学者
2014.09—至今,中国民航大学,理学院,硕士生导师
2013.11—2018.11,中国民航大学,理学院,副教授
2010.06—2013.11,中国民航大学,理学院,讲师
2005.09—2010.06,南京大学,物理学院,博士(硕博连读)
2009.03—2009.09,香港理工大学,应用物理系,访问学者
2001.09—2005.07,鲁东大学,物电学院,学士
三、课程教学
本科生课程:普通物理、物理实验、近代物理实验、功能材料、材料物理性能、材料创新案例分析、企业调研。
研究生课程:功能陶瓷材料、功能材料。
四、学术兼职
中国稀土学会光电材料与器件专业委员会理事
国家自然科学基金委通讯评议专家
天津市科技专家库专家
上海市科技专家库专家
全国研究生教育评估监测专家库专家
MDPI-Photonics期刊客座编辑
中国民航大学学报青年编委
五、荣誉称号与获奖
●教育部与天津市课程思政教学名师
●天津市“131”创新型人才二层次
●天津市大学生课外学术科技作品竞赛优秀指导教师
●天津市物理学会青年科技奖获得者
●中国民航大学蓝天优秀人才
●中国民航大学蓝天青年学者
●中国民航大学十佳教师
六、主要研究方向和科研业绩
1)主要研究方向:
●智能响应型材料合成、分析与应用
●航空工程相关传感材料与器件
2)主要科研项目:
[1] 新型钨青铜铁电体局域微结构关联的上转换发光及其电场调控机理研究,国家自然科学基金面上项目,51772326,60万,2018.01-2021.12,主持。
[2] 先兆型铁电体钛酸铕中量子临界性与多铁性的研究,国家自然科学基金青年项目, 51102277,25万,2012.01-2014.12,主持。
[3] 新型OED基无铅绿色BLSF晶体薄膜电光多功能属性的研究,天津市自然科学基金青年项目,14JCQNJC03700,6万,2014.04-2017.03,主持。
[4] 铁电基智能芯片关键存储介质中光场诱导新型多态发光反转技术研究,天津市自然科学基金重点项目,22JCZDJC00010,20万,2022.10-2025.9,主持。
[5]单相稀土掺杂铁电上转换材料的合成与光、电性能的研究,中央高校科研项目,2017.01-2018.12,主持。
[6] 新型电控材料Sr1-xAxTi1-yByO3晶体薄膜的制备与表征,中央高校科研项目,2012.10-2014.09,主持。
[7] 固体氧化物燃料电池新型电极材料的应用研究,天津市自然科学基金面上项目,2015/05至2018/12,参与。
[8] 双钙钛矿对称电极在固体氧化物燃料电池上的应用研究,天津市教委科研项目,2018/05-2020/05,参与。
[9] 共掺杂Y2O3/Eu3+纳米材料的高压研究,国家自然基金青年基金,2014/01-2016/12,参与。
[10] 量子顺电体中铁电序与量子涨落的竞争与调控研究,国家自然科学基金面上项目,2011.01-2013.12,参与。
[11] 修正屏蔽库伦势下二维磁化尘埃等离子体波谱特性的研究,国家自然基金青年基金,2019.01-2021.12,参与。
[12] M87喷流的辐射模型及其在典型活动星系核喷流中的应用,国家自然基金联合培育项目,2013.01-2015.12,参与。
[13] 半金属庞磁电阻材料中无序效应的研究,国家自然基金青年基金,2007.01-2009.12,参与。
七、 论著目录
1)代表性学术论文
[1] T. Wei(魏通), B. Jia, L. Shen, C. Zhao, M. Wang, H. Zhang, Q. Hao, Q. Zhou, Y. Zhang, A new class of upconversion luminescence tuning materials based on non-photochromic reaction: Er3+-activated Ba0.7Sr0.3Nb2O6 ferroelectrics, Acta Mater. 205 (2021) 116557.
[2] J. Hou, P. Chen, A. Shukla, A. Krajnc, T. Wang, X. Li, R. Doasa, L.H.G. Tizei, B. Chan, D.N. Johnstone, R. Lin, T.U. Schülli, I. Martens, D. Appadoo, M.S. Ari, Z. Wang, T. Wei(魏通), S.-C. Lo, M. Lu, S. Li, E.B. Namdas, G. Mali, A.K. Cheetham, S.M. Collins, V. Chen, L. Wang, T.D. Bennett, Liquid-phase sintering of lead halide perovskites and metal-organic framework glasses, Science. 374 (2021) 621–625.
[3] L. Shen, T. Wei(魏通)*, Y. Shi, X. Wang, L. Wu, J. Cui, T. Zhang, H. Yu, Z. Li, Light–Heat and Light–Light Dual-Controlled Upconversion Luminescence and Photochromic Processes in Er-Activated Bi7Ti4NbO21 for Optical Information Storage, ACS Appl. Electron. Mater. 4 (2022) 776–786.
[4] J. Bi, T. Wei(魏通)*, L. Shen, F. Yang, C. Zhao, M. Wang, Q. Yang, Y. Lin, Tunable upconversion luminescence in new Ho3+/Yb3+‐doped SrBi4Ti4O15 photochromic ceramics for switching application, J. Am. Ceram. Soc. 104 (2021) 1785–1796.
[5] L. Shen, T. Wei(魏通)*, Y. Shi, H. Hao, S. Chen, J. Chen, H. Guan, Q. Zhou, Z. Li, Up-conversion luminescence regulation and its boosting by polarization in Er3+/Yb3+ doped SrBi8Ti7O27 photochromic ceramics for optical switching application, J. Alloys Compd. 883 (2021) 161024.
[6] T. Wei(魏通)*, F. Yang, B. Jia, C. Zhao, L. Liu, H. Zhang, Y. Zhang, J. Zhang, X. Yan, J. Yang, Reversible photoluminescence modulation in praseodymium-doped bismuth titanate ceramics for information storage based on photochromic reaction, Ceram. Int. 46 (2020) 18507–18517.
[7] T. Wei(魏通)*, B. Jia, L. Shen, C. Zhao, L. Wu, B. Zhang, X. Tao, S. Wu, Y. Liang, Reversible upconversion modulation in new photochromic SrBi2Nb2O9 based ceramics for optical storage and anti-counterfeiting applications, J. Eur. Ceram. Soc. 40 (2020) 4153–4163.
[8] F. Yang, B. Jia, T. Wei(魏通)*, C. Zhao, Q. Zhou, Z. Li, M. Du, M. Wang, Y. Liu, C. Xie, Reversible regulation of upconversion luminescence in new photochromic ferroelectric materials: Bi 4−x Er x Ti 3 O 12 ceramics, Inorg. Chem. Front. 6 (2019) 2756–2766.
[9] T. Wei(魏通)*, F. Yang, B. Jia, C. Zhao, M. Wang, M. Du, Q. Zhou, Y. Guo, Z. Li, High performance temperature sensing and optical heating of Tm3+- and Yb3+- codoped SrBi4Ti4O15 up-conversion luminescence nanoparticles, Ceram. Int. 45 (2019) 18084–18090.
[10] T. Wei(魏通)*, F. Yang, Q. Jing, C. Zhao, M. Wang, M. Du, Y. Guo, Q. Zhou, Z. Li, Optical multi-functionalities of Er3+- and Yb3+-sensitized strontium bismuth titanate nanoparticles, J. Alloys Compd. 801 (2019) 1–9.
[11] Y. Shi, F. Yang, C. Zhao, Y. Huang, M. Li, Q. Zhou, Q. Li, Z. Li, J. Liu, T. Wei(魏通)*, Highly sensitive up-conversion thermometric performance in Nd3+ and Yb3+ sensitized Ba4La2Ti4Nb6O30 based on near-infrared emissions, J. Phys. Chem. Solids. 124 (2019) 130–136.
[12] M. Li, Y. Shi, C. Zhao, F. Yang, Q. Li, X. Zhang, S. Wu, H. Chen, J. Liu, T. Wei(魏通)*, Up-conversion luminescence, thermometry, and optical heating properties of Er 3+ - and Yb 3+ -doped K 2 LaNb 5 O 15 submicro-particles synthesized by a simple molten salt method, Dalt. Trans. 47 (2018) 11337–11345.
[14] T. Wei(魏通)*, Y. Shi, Y.F. Xie, Z. Dong, C.Z. Zhao, Q.J. Zhou, C.C. Ding, S. Yuan, F.Y. Xiang, X. Guo, B.Y. Du, High temperature-sensing performance of Er- and Yb-codoped tungsten bronze oxides based on frequency up-conversion luminescence, Mater. Res. Bull. 88 (2017) 206–213.
[15] T. Wei(魏通)*, Z. Dong, C.Z. Zhao, Y.Y. Guo, Q.J. Zhou, Z.P. Li, Structural and relaxor-like dielectric properties of unfilled tungsten bronzes Ba 5−5x Sm 5x Ti 5x Nb 10−5x O 30, J. Appl. Phys. 119 (2016) 124107.
[16] Z. Dong, T. Wei(魏通)*, Y.J. Ma, T.B. Zhang, X.X. Lian, Y.Y. Guo, F.M. Yang, D.M. An, Influence of erbium substitution on structural, electrical, and up-conversion photoluminescence properties of unfilled tungsten bronze oxides Ba3.75La0.833-xErxNb10O30, J. Alloys Compd. 681 (2016) 240–252.
[17] T. Wei(魏通)*, T.B. Zhang, Y.J. Ma, Y.F. Xie, C.Z. Zhao, F.M. Yang, H.Y. Xiao, Y. Zhao, Up-conversion photoluminescence and temperature sensing properties of Er3+-doped Bi4Ti3O12nanoparticles with good water-resistance performance, RSC Adv. 6 (2016) 7643–7652.
[18] T. Wei(魏通)*, Z. Dong, C.Z. Zhao, Y.J. Ma, T.B. Zhang, Y.F. Xie, Q.J. Zhou, Z.P. Li, Up-conversion luminescence and temperature sensing properties in Er-doped ferroelectric Sr 2 Bi 4 Ti 5 O 18, Ceram. Int. 42 (2016) 5537–5545.
[19] Y.F. Xie, Z. Dong, T. Wei(魏通)*, C.Z. Zhao, Q.G. Song, T.B. Zhang, S. Yuan, F.Y. Xiang, Up-conversion thermometric properties of nanorod-like K2Bi0.98−xEr0.02YbxNb5O15, Mater. Lett. 184 (2016) 286–290.
[20] T. Wei(魏通)*, C.P. Li, Q.J. Zhou, Z.P. Li, P. Li, J. Wu, X.F. Yang, Structure, upconversion photoluminescence, and dielectric properties of Ho3+- and Yb3+-codoped tetragonal tungsten bronze Sr4La2Ti4Nb6O30, Mater. Res. Bull. 64 (2015) 395–400.
[21] T. Wei(魏通)*, Z. Dong, C.Z. Zhao, P. Li, J. Wu, G.X. Tong, Modifying optical, electric and magnetic properties of multifunctional Gd3+-doped Ba4La0.95Er0.05TiNb9O30 ceramics, Mater. Lett. 152 (2015) 135–138.
[22] T. Wei(魏通)*, L. Ye, C.Z. Zhao, W.B. Wang, Q.Z. Ma, Q. Lv, J.M. Liu, Engineering the A- and B-sites for upconversion luminescence in Ho- and Yb-codoped filled tetragonal tungsten bronze oxides, J. Mater. Sci. 50 (2015) 2480–2490.
[23] T. Wei(魏通)*, Z. Dong, C.Z. Zhao, P. Li, J. Wu, L.J. Liu, Y.J. Ma, H.Y. Xiao, Structure and upconversion analyses of Er3+-doped Ba6Ti2Nb8O30–Sr6Ti2Nb8O30 solid solutions, Ceram. Int. 41 (2015) 8915–8920.
[24] T. Wei(魏通)*, X.D. Wang, C.Z. Zhao, T.B. Zhang, F.M. Yang, W.B. Wang, Y.J. Ma, Enhanced up-conversion photoluminescence and dielectric properties of Er- and Zr-codoped strontium bismuth niobate ceramics, Ceram. Int. 41 (2015) 12364–12370.
[25] T. Wei(魏通)*, Y.Q. Wang, C.Z. Zhao, X.X. Dong, J.H. Wang, Upconversion photoluminescence and dielectric properties in Er3+ and Yb3+ co-doped Sr4La2Ti4Nb 6O30, Mater. Lett. 128 (2014) 152–155.
[26] T. Wei(魏通)*, Y.Q. Wang, C.Z. Zhao, L.Q. Zhan, Photoluminescence and electrical characterization of unfilled tetragonal tungsten bronze Ba4La1 - XEuxTiNb 9O30, Mater. Res. Bull. 60 (2014) 111–117.
[27] T. Wei(魏通)*, C.P. Li, Q.J. Zhou, Y.L. Zou, L.S. Zhang, Upconversion luminescence and ferroelectric properties of Er3+ doped Bi4Ti3O12-SrBi4Ti 4O15, Mater. Lett. 118 (2014) 92–95.
[28] T. Wei(魏通)*, Y.Q. Wang, Q.J. Zhou, Z.P. Li, L.Q. Zhan, Q. Jin, Bright reddish-orange emission and enhanced electrical properties of Sm-doped unfilled tetragonal tungsten bronze Ba 4 LaTiNb 9 O 30, Ceram. Int. 40 (2014) 16647–16651.
[29] T. Wei(魏通)*, C.Z. Zhao, Q.J. Zhou, Z.P. Li, Y.Q. Wang, L.S. Zhang, Bright green upconversion emission and enhanced ferroelectric polarization in Sr1−1.5xErxBi2Nb2O9, Opt. Mater. (Amst). 36 (2014) 1209–1212.
[30] T. Wei(魏通)*, X.D. Wang, C.Z. Zhao, M.F. Liu, J.M. Liu, Correlation between upconversion photoluminescence and dielectric response in Ba-substituted (Sr 1−x Ba x ) 4 (La 0.85 Ho 0.025 Yb 0.125 ) 2 Ti 4 Nb 6 O 30, Appl. Phys. Lett. 104 (2014) 261908.
[31] T. Wei(魏通)*, Z. Chang, Q.J. Zhou, D.M. An, Z.P. Li, F.C. Sun, Bright green emission in Ho doped Bi1/2Na1/2TiO3 ferroelectric ceramics, Mater. Lett. 115 (2014) 129–131.
[32] T. Wei(魏通)*, C.Z. Zhao, C.P. Li, Y.B. Lin, X. Yang, H.G. Tan, Photoluminescence and ferroelectric properties in Eu doped Bi 4Ti3O12-SrBi4Ti4O 15 intergrowth ferroelectric ceramics, J. Alloys Compd. 577 (2013) 728–733.
[33] T. Wei(魏通)*, F.C. Sun, C.Z. Zhao, C.P. Li, M. Yang, Y.Q. Wang, Photoluminescence properties in Sm doped Bi1/2Na 1/2TiO3 ferroelectric ceramics, Ceram. Int. 39 (2013) 9823–9828.
[34] T. Wei(魏通)*, C.Z. Zhao, C.P. Li, L.Q. Zhan, Q. Jin, X.F. Yang, Enhanced ferroelectric and photoluminescence properties in Sr 1-1.5xHoxBi2Nb2O9 ceramics, Mater. Res. Bull. 48 (2013) 4314–4318.
[35] T. Wei(魏通)*, Q.J. Zhou, C.Z. Zhao, Y.B. Lin, Y.L. Zou, Y. Li, L.S. Zhang, Strong green light emission in Ho doped Bi 4 Ti 3 O 12 ferroelectric ceramics, Ceram. Int. 39 (2013) 7211–7215.
[36] T. Wei(魏通), Q.J. Zhou, Q.G. Song, Z.P. Li, S.Q. Guo, Y.R. Guo, Y.F. Chen, X.L. Qi, J.-M. Liu, The interaction of multifold polar orderings in Ba-doped Sr0.7Ca0.3TiO3, Mater. Res. Bull. 47 (2012) 1316–1322.
[37] T. Wei(魏通), Q.J. Zhou, X. Yang, Q.G. Song, Z.P. Li, X.L. Qi, J.M. Liu, Competition between quantum fluctuation and ferroelectric order in Eu 1-x Ba x TiO 3, Appl. Surf. Sci. 258 (2012) 4601–4606.
[38] T. Wei(魏通), Q.G. Song, Q.J. Zhou, Z.P. Li, Y.F. Chen, X.L. Qi, S.Q. Guo, J.-M. Liu, Giant dielectric tunable behavior of Pr-doped SrTiO 3 at low temperature, Funct. Mater. Lett. 05 (2012) 1250018.
[39] T. Wei(魏通), H.P. Liu, Y.F. Chen, H.Y. Yan, J.M. Liu, Preparation, magnetic characterization, and optical band gap of EuTiO 3 nanoparticles, Appl. Surf. Sci. 257 (2011) 4505–4509.
[40] T. Wei(魏通), Q.G. Song, Q.J. Zhou, Z.P. Li, X.L. Qi, W.P. Liu, Y.R. Guo, J.M. Liu, Cr-doping induced ferromagnetic behavior in antiferromagnetic EuTiO 3 nanoparticles, Appl. Surf. Sci. 258 (2011) 599–603.
[41] T. Wei(魏通), J.-M. Liu, Q.J. Zhou, Q.G. Song, Coupling and competition between ferroelectric and antiferroelectric states in Ca-doped Sr0.9−xBa0.1CaxTiO3: Multipolar states, Phys. Rev. B. 83 (2011) 052101.
[42] T. Wei(魏通), H.M. Liu, C. Zhu, Y.J. Guo, J.-M. Liu, Y.J. Wu, X.M. Chen, Size-dependent structural preferences and magnetization enhancement in 0.5Bi0.8La0.2FeO3–0.5PbTiO3, J. Appl. Phys. 108 (2010) 124108.
2)授权国家发明专利:
[1] 魏通,谢一帆,董泽. 一种高灵敏度稀土掺杂钨青铜荧光探温材料, 中国,国家发明专利,CN201610300741.0.
[2] 魏通,贾兵,申灵慧. 一种上转换发光可逆调控材料及其制备方法, 中国,国家发明专利,CN 202010241683.5.
[3] 魏通,杨丰铭,申灵慧. 基于光致变色效应的上转换发光可逆调控材料及制备方法, 中国,国家发明专利,ZL202010335674.2.
[4] 魏通,申灵慧,石永超. 具有可逆调控性能的共生层状钙钛矿材料及制备方法, 中国,国家发明专利,ZL202011073586.6.
[5] 魏通,石永超,闫家伟,王翔宇. 一种钨青铜基光致变色陶瓷材料及其制备方法, 中国,国家发明专利,ZL202210543468.X.
[6] 魏通,王翔宇,吕志宏,石永超,张博睿. 一种钙钛矿型高熵陶瓷材料及其制备方法, 中国,国家发明专利,202210726143.5.
3)出版书籍:
普通物理实验教程,高等教育出版社, 2015年,参编。
