个人信息


个人简介
个人简介
大学开始受教育经历
1998－2002,吉林大学，材料科学与工程学院,本科
2003－2006,电子科技大学,电子薄膜与集成器件国家重点实验室,硕士，导师：张万里教授
2006－2010,电子科技大学,电子薄膜与集成器件国家重点实验室,博士，导师：李言荣教授（院士）
2007.10－2008.9,新加坡国立大学，材料科学与工程系，研究实习生，
2008.10－2009.10,新加坡国立大学，材料科学与工程系，联合培养博士生，
2011年2月至今，苏州大学物理科学与技术学院，薄膜材料江苏省重点实验室，讲师, 副教授




研究领域
自旋电子学（Spintronics）、氧化物多铁材料、5G/6G微波材料与器件，具体包括
1. 磁性薄膜/纳米结构磁电性质的多场调控
2. 柔性磁电材料与器件
3. 5G/6G通讯微波材料与器件
主持国家自然科学基金项目、科技部重点研发计划项目参与课题、省部级科研项目5项，市厅级项目3项，参与国家级科研项目4项。在该方向发表SCI/EI收录论文40余篇，申请专利8项。


基本信息






汤如俊
职称：副教授
院部/部门：物理科学与技术学院
学历：博士
学位：
毕业学校：
毕业专业：

联系方式


通讯地址：
邮政编码：
电子邮箱：tangrj@suda.edu.cn
联系电话：
传真号码：
办公地点：苏大物理科技楼





科学研究



自旋电子学（Spintronics）、氧化物多铁材料、5G/6G微波材料与器件，具体包括
1. 磁性薄膜/纳米结构磁电性质的多场调控
2. 柔性磁电材料与器件
3. 5G/6G通讯微波材料与器件



2. 主持和参与的科研项目:
（1）多铁性六角铁氧体有序微纳米结构的磁学和磁电性质研究，国家自然科学基金面上项目（2018.1至2021.12）,主持
（2）晶圆级敏感薄膜材料微结构与宏观电磁性能关系研究,国家重点研发计划项目“高性能无源敏感薄膜材料Si基异质异构集成方法及传感器芯片研发”（参与单位子课题）,(2017.7至2021.6),主持
（3）掺杂M型铁氧体薄膜的磁学、介电和磁介电性质研究,电子薄膜与集成器件国家重点实验室开放基金项目,(2015.10至2017.10),主持
（4）掺杂M型铁氧体的软磁、介电和高频性质研究,多频谱技术教育部重点实验室开放基金项目,(2015.1至2016.12),主持
（5）Co基Z型六角铁氧体薄膜室温巨磁电耦合效应研究,国家自然科学基金青年基金项目,(2013.1-2015.12)，,主持
（6）Co2Z型六角铁氧体薄膜室温巨磁电耦合效应研究,教育部中央支持高校博士点基金新教师项目,(2013.1-2015.12),主持
（7）氧化物薄膜中的多维应变效应研究,国家自然科学基金面上项目,(2013.1至2016.12)，参加
（8）Exchange-coupled Perpendicular Magnetic Recording Media,A*STAR, Singapore,(2007年-2009年,参加
（9）柔性FeCoSiB非晶磁弹性薄膜的应力阻抗效应研究,国家自然科学基金面上项目,(2006.1至2009.12),参加
（10）高灵敏度交换耦合磁致伸缩薄膜材料的研究,国家自然科学基金面上项目，（2003.1月至2006.12),参加
（11）PSV、MTJ材料电子自旋极化效应研究,国防973项目子课题,（2002.1至2006.12）,参加


3. 主要科研设备:
1）脉冲激光镀膜系统Pulsed Laser Deposition (PLD):
2）综合物理性能测试系统Physical Property Measurement System (PPMS):磁性和半导体综合变温测试平台
3）高真空磁控溅射镀膜系统；
4）Spin-coating 镀膜机
5）Keithely 6517，Keithely2400,Keithely2182 等高精度电学测试仪表及探针台
6）AgilentE4980 LCR介电测试仪表
7）RadiantMultiferroic 铁电测试仪
8）矢量网路分析仪







科研团队


培养硕士研究生9名（已毕业3名），联合培养在读博士研究生1名。



论文


[1] Selected Publications (Classified with research projects)：
1. Magnetic, Dielectric and MagnetodielectricProperties of Magnetoelectric Hexaferrites

[1] J.J Zhang, W.L.Kong, R. J. Tang*, X.D.Su*, J.S.Chen* et’al,Piezoelectric control of resistance switching in VO2/Pb(Zr0.52Ti0.48)O3 thin film heterostructure, Applied Physics Letters. 114, 061603 (2019).

[2] Q.S.Zhu, R.J. Tang* H. Zhou, et’al, Impedance spectroscopy and conduction mechanism of magnetoelectric hexaferrite BaFe10.2Sc1.8O19, Journal of the American Ceramics Society,00：1-10.(2018)

[3] C.R. Li, S.M. Zhang, R.J. Tang, Y.Lifshitz,* Le He,* X.H. Zhang* et'al, Curvature-Controlled Non-Epitaxial Growth of Hierarchical Nanostructures, Angew.Chem. Int. Ed. 57, 1 – 6 (2018)

[4] W.H. Zhang, Q.S.Zhu, R.J. Tang* et’al, Temperature dependent magnetic properties of conical magnetic structure M-type hexaferrites BaFe10.2Sc1.8O19 and SrFe10.2Sc1.8O19, Journal of Alloys and Compounds, 750,368e374(2018).

[5] H. Zhou, R. J. Tang*, H.P. Lu, et’al, Phase formation and magnetic property evolution processes of hexaferrite with composition BaO﹒0.9Sc2O3﹒5.1Fe2O3, Journal of Materials Science: Materials in Electronics, p1-7(2017).

[6]R. J. Tang*, H.Zhou, H. Yang*et’al, Room-temperature magnetodielectric effects in epitaxial hexaferrite BaFe10.2Sc1.8O19 thinfilm, Applied Physics Letters. 110, 242901 (2017).

[7] R. J. Tang*,H.Zhou, H.Yang*,Room-temperature multiferroic and magneto-capacitance effects in M-type hexaferrite BaFe10.2Sc1.8O19, Applied Physics Letters. 109, 082903(2016). [Editor's Pick]

[8] R. J. Tang*, Z. Hao, H. Yang etal.,Dielectric relaxation and polaronic conduction in epitaxial BaFe12O19 hexaferrite thin film，Journal of Physics D: Applied Physics,49, 1-6 (2016).

[9] R. J. Tang*, C. Jiang, H. Zhou, H.Yang*, Effects of composition and temperature on the magnetic properties of(Ba,Sr)3Co2Fe24O41 Z type hexaferrites, Journal of Alloys and Compounds,658,132(2016).

[10] R. J. Tang*, C. Jiang, Y. Fang, H.Yang*, Chemical states of air annealed Sr3Co2Fe24O41 Z-type hexaferrite- an X-ray photoelectron spectroscopy study, Materials Technology: Advanced Performance Materials, 30(A4), 1 (2016).

[11] R. J. Tang*, C.Jiang, H.Yang*et al., Impedance spectroscopy and scaling behaviors of Sr3Co2Fe24O41 hexaferrites, Applied Physics Letters,106, 022902 (2015).

[12] R. J. Tang*, C.Jiang, H.Yang*et al., Dielectric relaxation, resonance and scaling behaviors in Sr3Co2Fe24O41 hexaferrite”, Scientific Reports, 5,13645 (2015).



2.Electric and Magnetoelectric Properties of Oxide nanocomposites.

[13] Z.J.Shi, Z.H. Jiang, R. J. Tang* et al., Study on the Effects of Oxygen Vacancy in SrCoOx Thin Films, Applied Physics, 6, 205-211(2016).

[14] Z.H. Jiang, Z.J.Shi, R. J. Tang* et al., Effect of Post-Anneal and NaClO Oxidation on the Properties of SrCoOx Epitaxial Thin Films, Applied Physics, 6, 219-225(2016).

[15] X. Lu, R. J. Tang*, H. Yang*, SrMnO3 Film Grown by Pulsed Laser Deposition. Applied Physics, 5,1-7(2015).

[16] W. W. Li, W. Zhang, R.J. Tang, Hao Yang* et al.,Vertical Interface Induced Dielectric Relaxation in Nanocomposite (BaTiO3)1-x:(Sm2O3)x Thin Films, Scientific Reports 5, 11335 (2015)

[17] R.Zhao, W.W. Li, R. J. Tang, H. Yang*et al.,Precise tuning of (YBa2Cu3O7-δ)1-x:(BaZrO3)x thin film nanocomposite structures”, Advanced Functional Materials, 24(33), 5240(2014).

[18] R.Zhao, W.W. Li, R. J. Tang, H.Yang*et al., Manipulating leakage behavior via distribution of interfaces in oxide thin films, Applied Physics Letters, 105, 072907 (2014).

[19] W.W.Li, R. Zhao,R. J. Tang, H.Yang*,et’al. Vertical-interface-manipulated conduction behavior in nanocomposite oxide thin films, ACS: Appl. Mater.Interfaces,6, 5356 (2014)

[20] R.Zhao, W.W. Li, R. J. Tang, H. Yang*,et’al. Manipulating leakage behavior via distribution of interfaces in oxide thin films, Applied Physics Letters, 8, 101 (2014).

[21] W.W.Li, R. Zhao, R. J. Tang, H.Yang*, et’al. Oxygen-Vacancy-Induced Anti-ferromagnetism to Ferromagnetism Transformation in Eu0.5Ba0.5TiO3 thin film, Scientific Reports, 3, 2618 (2013).

[22] R.Zhao, W.W. Li, R. J. Tang*, H. Yang*, et’al. Conduction mechanisms of the EuTiO3 epitaxial thin film, AppliedPhysics Letters, 8, 101 (2012).




3. CoPt and FePt Based Nanocomposites for PerpendicularMagnetic Recording Media.

[23]R. J. Tang*, P.Ho, Growth of Ru–SiO2 underlayerfor Co72Pt28–SiO2 nanocomposite films , Phys. Stat.Solidi (A): Appl &Mater. Sci., 3, 1162-1167 (2014).

[24] R. J. Tang*, W. L. Zhang, Y.R. Li et’al. Effects of soft layer anisotropy and thickness on the magnetic properties of the soft/hard perpendicular exchange-coupled nanocomposite films, Journal of Magnetism and Magnetic Materials. 323, 2569-2574 (2011).

[25] R. J. Tang*, W. L. Zhang, Y.R. Li et’al., Effects of TiO2 volume fraction on the microstructure and magnetic properties of CoPt-TiO2 nanocomposite films.”, Science China:Physics, Mechanics and Astronomy, 54, 1283-1288(2011).

[26] R. J. Tang*, W. L. Zhang, Y.R. Li et’al., Microstructure and magnetic properties of the CoPtRu-SiO2 single andCoPtRu-SiO2/Co72Pt28-SiO2 double layer nanocomposite films, Materials Science Forum, 688, 358-363(2011).

[27] R. J. Tang*, P. Ho, B. C.Lim, Influence of Ru/Ru-SiO2 underlayers on the microstructure and magnetic properties of CoPt-SiO2 perpendicular recording media., Thin Solid Films, 518, 5813-5819 (2010).

[28] R. J. Tang*, W. L. Zhang, Y.R. Li et’al., Microstructure and magnetic properties of CoPt-TiO2 nanocomposite films prepared by annealing CoPt/TiO2 multi-layers., Journal of Magnetism and Magnetic Materials.322, 3490-3494 (2010).

[29] R. J. Tang*, W. L. Zhang, Y.R. Li et’al., Annealing environment effects on the microstructure and magnetic properties of FePt-TiO2 and CoPt-TiO2 nanocomposite films, Journal of Alloy and Compounds, 496, 380-384 (2010).

4.Micromagnetic Simulation of Patterned Magnetic Thin films.

[30] S.C. Xu, J.F. Yin, R.J. Tang*, et’al., Effects of the shape anisotropy and biasing field on the magnetization reversal process of the diamond-shaped NiFe nano films, Physica B: Condensed Materials, 525, 26-29(2017).

[31] R. J. Tang*, W. L. Zhang, H.W. Zhang et’al., The spontaneous and remanencedomain states of diamond-shaped NiFe nano films, Research and Progress inSolid State Electronics, 27,24-27 (2007). [In Chinese]

[32] W. L. Zhang, R. J. Tang*,H.W. Zhang et’al., Electric current model in the Magnetic Random Access Memory, Research and Progress inSolid State Electronics, 26, 307-311 (2006). [In Chinese]

[33] W.L. Zhang, R. J. Tang,H.W. Zhang et’al., Magnetization reversal behavior simulation of diamond shaped NiFe nano film elements, IEEE Transaction on Magnetism, 41, 4390-4393 (2005).

[34] W.L. Zhang, R. J. Tang*, H.W. Zhang et’al., Simulation of the magnetization reversal process of rectangle-shaped NiFe film elements under an orthogonal magnetic field.”, Acta Metallurgica Sinica,18, 642-646(2005).

5.Flexible Magnetic Thin films.

[35] J.D. Liu,* Y. Feng, R.J.Tang, R. Zhao, H.Yang* et’al., Mechanically Tunable Magnetic Properties ofFlexible SrRuO3 Epitaxial Thin Films on Mica Substrates, Adv. Electron. Mater. **(2018).

[36] W.L. Zhang, B. Peng, R. J. Tang et’al., Stress impedance effects in flexible amorphous FeCoSiB magnetoelastic films”, Journal ofMagnetism and Magnetic Materials. 320, 1958-1960 (2008).

[37] R.J.Tang*, Q.Y.Xie, B.Peng et al., Influences of Ar pressure on the surface morphology and magnetic properties of FeCoSiB amorphous thin film. Journal of Functional Materials. 38, 1114-1116(2007). [In Chinese]

[38] B. Peng, W.L. Zhang, R. J. Tang et’al., Magnetic anisotropyproperties of FeCoSiB amorphous thin film grown under stress. Journal of Functional Materials. 38, 1111-1113(2007). [In Chinese]

荣誉奖励


1、优秀毕业研究生（硕士）,电子科技大学,2006年




开授课程


一、课程
1. 《普通物理学》
2. 《专业实验》
3.《纳米材料与薄膜技术》（全英文课程）

二、获奖
1.指导学生获2017年江苏省大学生物理实验作品竞赛二等奖，优秀指导教师。
2.指导学生获2019年江苏省大学生物理实验作品竞赛二等奖，优秀指导教师。

招生信息


欢迎对智能薄膜磁电材料、微电子材料与器件感兴趣的同学加入本实验室！




研究项目（旧版）

荣誉奖励（旧版）

科研成果（旧版）