授课情况

1. 储能聚合物电介质基础理论，32学时，本科生课程

2. 电介质基础，32学时，本科生课程

3.电工新材料概论，32学时，研究生课程

4. 介电高分子材料前沿，32学时，研究生课程

招生情况

1. 每年招生1-2名直博生或普博生

2. 每年招生2-3名本科毕业论文设计学生

3. 每年招收2-3名博士后

科研项目：

2025.08-2029.07，智能电网国家科技重大专项：高能量密度直流电容器用耐高温薄膜材料关键技术 (2025ZD0808400)

2021.12-2025.11, 国家重点研发计划重点专项：干式直流电容器用电介质薄膜材料(2021YFB2401500)

2022.01-2023.12，XXX专项：XXX弹性体及应用验证 (211-CXCY-N103-01-02-01)

2025.01-2029.12，国家自然科学基金委员会重点项目：介电弹性体柔性无磁电机性能强化基础理论与方法 (52437002)

2020.01-2024.12，国家自然科学基金委员会重点项目：脉冲功率电容器用高储能复合电介质结构性能调控的基础理论与演示验证 (51937007)

2025.01-2029.12，国家自然科学基金委员会创新群体：高电压与绝缘技术 (51921005)

2025.01-2029.12，国家自然科学基金委员会杰青项目：无机/有机介电功能复合材料设计与实现 (51425201)

2014.01-2017.12，国家自然科学基金委员会面上项目：高介电全有机复合薄膜中定向有序纳微阵列结构控制及其与介电性能关联机制 (51377010)

2011.01-2013.12，国家自然科学基金委员会面上项目：1-3型碳管/硅橡胶纳米复合材料设计、制备与新颖压阻机制及介电性能的研究 (51073015)

2010.01-2012.12，国家自然科学基金委员会面上项目：基于介电性能变化的颗粒填充型复合电介质纳米效应的机理研究 (50977001)

2007.01-2009.12，国家自然科学基金委员会面上项目：微-纳米钛酸钡共填充的聚合物基复合材料介电性能提高的机制研究 (50677002)

2004.01-2004.12，国家自然科学基金委员会青年项目：LTNO陶瓷粉末填充的铁电聚合物基复合材料介电特性探索 (50373024)

2010.07-2013.06，科技部国际合作项目：新型多功能纳米复合材料制备及其拉、压应力作用下的介电特性研究 (2010DFA51490)

2008.01-2010.12，科技部863项目：高储能密度聚合物基纳米复合电介质薄膜的规模化制备技术 (2008AA03Z307)

2014.01-2018.12，科技部973项目：纳米固体绝缘介质电场及热场下的微结构调控理论及方法 (2014CB239503)

2014.01-2016.12，教育部博士点优先基金项目：核壳结构纳米颗粒调控介电高分子复合材料界面结构和综合电性能 (20130006130002)

2008.01-2010.12，教育部新世纪人才项目：高介电常数聚合物基电介质复合材料的基础科学问题研究

2021.12-2023.11，北京中关村概念验证项目：高导热绝缘材料封装提升高频高压电力电子器件性能的验证

2013.12-2015.11，北京市科委新材料项目：100KV高压直流电缆料研制

2008.01-2010.12，北京市自然科学基金项目：电活性硅橡胶基复合材料的电致伸缩行为及其性能提高的机制 (2122040)

2017.01-2019.12，国家电网公司横向项目：兼顾高功率高能量密度的薄膜介质电力电容器关键技术研究 (5202011600UK)

2017.01-2019.12，国家电网公司横向项目：高压直流输电用大容量薄膜介质电容器关键技术研究 (SGRDGKJ[2017]634)

2018.01-2020.06，国家电网公司横向项目：船舶用岸电专用电缆关键技术研究与应用

2016.01-2018.12，国家电网公司横向项目：高导热环氧绝缘封装材料关键技术研究及应用

2016.08-2018.07，中车株洲电力机车横向项目：兼具高导热与高绝缘性能纳米复合硅橡胶分级结构设计与性能优化策略

2022.05-2022.11，东方电气集团东方电机横向项目：基于多物理场耦合仿真技术分析深度调峰对汽轮发电机 绝缘系统的影响 (YJJKQT012-2022)

2024.04-2025.06，东方电气集团东方电机横向项目：高海拔水轮发电机防晕系统失效过程的精细化仿真及关键特征的测试技术 (YFJYKQT014-2024)

2024.04-2025.12，东方电气集团东方电机横向项目：极端服役条件下绝缘结构的破坏机制模拟及先进表征分析 (YFJYKQT013-2024)

中英文著作 (共10部)

1. 党智敏 著. 储能聚合物电介质导论, 科学出版社, 2021.

2. 党智敏 著. 绝缘封装与聚合物介质材料，清华大学出版社，2025

3. 周文英，党智敏，丁小卫 等著. 聚合物基导热复合材料 国防工业出版社，2017.

4. Zhi-Min Dang (Editor). Dielectric Polymer Materials for High-Density Energy Storage, Elsevier, 2018.

5. Jun-Wei Zha, Zhi-Min Dang (Editor). High Temperature Polymer Dielectrics-Fundamentals and Applications in Power Equipment, Wiley, 2023

6. Zhi-Min Dang, Chapter 6-Polymer Nanocomposites with High Permittivity, in: Nanocrystalline Materials: Their Synthesis-Structure-Property Relationships and Applications, Edited by S. C. Tjong, Elsevier, 2013.

7. Li-Juan Yin, Zhi-Min Dang, Chapter 8-Nanodielectric Elastomers for Flexible Generators, in: Flexible Energy Conversion and Storage Devices, Edited by Chunyi Zhi and Liming Dai, Wiley-VCH, 2018.

8. Zhi-Min Dang, Ming-Sheng Zheng, Jun-Wei Zha, Chapter 6-Ferroelectric Polymer Materials for Electric Energy Storage, in: Ferroelectric Materials for Energy-Related Applications, Edited by Haitao Wang and James F. Scott, Wiley-VCH, 2018.

9. Minhao Yang, Zhi-Min Dang, Chapter 11-Future prospects: polymer part, Advanced Dielectric Materials for Electrostatic Capacitors, Edited by Qi Li, The Institution of Engineering and Technology, 2020.

10. Jun-Wei Zha, Ming-Sheng Zheng, Wei-Kang Li, George Chen, Zhi-Min Dang, Chapter 5-Polypropylene Insulation Materials for HVDC Cables, in: Polymer Insulation Applied for HVDC Transmission, Edited by Boxue Du, Springer, 2020.

代表性论文

 

在Nature Reviews Electrical Engineering、Nature Communications (4篇)、Advanced Materials (15篇)、Energy & Environmental Science、Applied Physics Letters (40篇)等共发表各类期刊论文460多篇，其中SCI论文350余篇，SCI他引23000多次(截止2025年05月)，个人H指数81。单篇SCI引用超过100次的论文45篇，超过1000次引用的论文2篇。

特邀综述类(Invited Review)

[1]Tian-Yu Wang, Jie Mao*, Boya Zhang*, Gui-Xin Zhang*, Zhi-Min Dang*.  Polymeric insulating materials characteristics for high-voltage applications. Nature Reviews Electrical Engineering, 2024, 1, 516-528.

[2]Qi-Kun Feng, Shao-Long Zhong, Jia-Yao Pei, Yu Zhao, Dong-Li Zhang, Di-Fan Liu, Yong-Xin Zhang, Zhi-Min Dang*. Recent progress and future prospects on all-organic polymer dielectrics for energy storage capacito rs. Chemical Reviews, 2022, 122(3), 3820-3878.

[3]Minhao Yang*, Yanlong Zhao, Huarui Yan, Zepeng Wang, Chao Xu*, Chong Zhang, Emiliano Bilotti*, Jianying Li, Zhi-Min Dang*. Electrostatic interaction bridges the charge transport kinetics and high-temperature ca pacitive energy storage performance of polymer dielectrics. Energy & Environmental Science, 2024, 17(20),7627-7648.

[4]Xue-Jie Liu, Ming-Sheng Zheng*, George Chen, Zhi-Min Dang*, Jun-Wei Zha*. High-Temperature Polyimide Dielectric Materials for Energy Storage: Theory, Design, Preparation and Properties. Energy & Environmen tal Science, 2022, 15(1), 56-81.

[5]Minhao Yang*, Qingmin Li, Xianming Zhang, Emiliano Bilotti, Chong Zhang, Chao Xu, Shenghua Gan*, Zhi-Min Dang*. Surface engineering of 2D dielectric polymer films for scalable production of High-Energy-De nsity films. Progress in Materials Science, 2022, 128, 100968.

[6]Zhi-Min Dang*, Jin-Kai Yuan, Jun-Wei Zha, Tao Zhou, Sheng-Tao Li, Guo-Hua Hu*. Fundamentals, processes and applications of high-permittivity polymer-matrix composites. Progress in Materials Science, 2012, 57, 660-723.

[7]Jia-Yao Pei, Li-Juan Yin, Shao-Long Zhong, Zhi-Min Dang*. Suppressing the loss of polymer-based dielectrics for high power energy storage. Advanced Materials, 2023, 35(3), 2203623.

[8]Jing Qin, Li-Juan Yin, Ya-Nan Hao, Shao-Long Zhong, Dong-Li Zhang, Ke Bi, Yong-Xin Zhang, Yu Zhao, Zhi-Min Dang*. Flexible and stretchable capacitive sensors with different microstructures. Advanced Materials, 2021, 33, 2008267.

[9]Zhi-Min Dang*, Jin-Kai Yuan*, Sheng-Hong Yao, Rui-Jin Liao. Flexible nanodielectric materials with high permittivity for power energy storage. Advanced Materials, 2013, 25(44), 6334-6365.

[10]Yong-Xin Zhang, Qi-Kun Feng, Shao-Long Zhong, Jia-Yao Pei, Fang-Yi Chen, Guan-Nan He, Zhi-Min Dang*. Digital twin accelerating development of metallized film capacitor: Key issues, framework design and pro spects. Energy Reports, 2021, 7704-7715.

[11]Jun-Wei Zha*, Ming-Sheng Zheng, Ben-Hui Fan, Zhi-Min Dang*. Polymer-based dielectrics with high permittivity for electric energy storage: A Review. Nano Energy, 2021, 89, 106438.

[12]Zhi-Min Dang*, Ming-Sheng Zheng, Jun-Wei Zha*. 1D/2D Carbon Nanomaterial-polymer Dielectric Composites with High Permittivity for Power Energy Storage Application. Small, 2016, 12(13), 1688-1701.

[13]Zhi-Min Dang*, Ming-Sheng Zheng, Peng-Hao Hu, Jun-Wei Zha. Dielectric Polymer Materials for Electrical Energy Storage and Dielectric Physics: A Guide. Journal of Advanced Physics, 2015, 4(4), 302-313.

[14Zhi-Min Dang*, Jin-Kai Yuan, Jun-Wei Zha, Peng-Hao Hu, Dong-Rui Wang, Zhong-Yang Cheng. High-permittivity polymer nanocomposites: Influence of interface on dielectric properties. Journal of Advanced Dielectr ics, 2013, 3, 1330004

[15]Yang Yang, Zhi-Min Dang, Qi Li*, Jiangliang He*. Self-Healing of Electrical Damage in Polymers. Advanced Science, 2020, 7(21), 2002130.

[16]Shao-Long Zhong, Zhi-Min Dang*, Wen-Ying Zhou, Hui-Wu Cai. Past and future on nanodielectrics. IET Nanodielectrics, 2018, 1(1), 41-47.

科学研究类(Research Article)

[1]Kun Xing, Yanan Hao, Xin-Jie Wang, Lei Huang, Yi Gao, Tong Liang, Yan Meng, Ke Bi*, Shao-Long Zhong*, Zhi-Min Dang*. Enhanced energy storage performance of nano-submicron structural dielectric films by suppr essed ferroelectric phase aggregation. Nature Communications, 2025, 16, 2006.

[2]Yajie Hu, Puying Li, Guobin Lai, Bing Lu, Haiyan Wang, Huhu Cheng, Mingmao Wu, Feng Liu, Zhi-Min Dang, Liangti Qu*. Separator with high ionic conductivity enables electrochemical capacitors to line-filter at high power. Nature Communications, 2025, 16, 2772.

[3]Li-Juan Yin, Yu Zhao, Jing Zhu, Minhao Yang, Huichan Zhao, Jiayao Pei, Shao-Long Zhong, Zhi-Min Dang*. Soft, tough, and fast polyacrylate dielectric elastomer for non-magnetic motor. Nature Communications, 2021, 12, 4517.

[4]Li-Juan Yin, Boyuan Du, Hui-Yi Hu, Wen-Zhuo Dong, Yu Zhao, Zili Zhang, Huichan Zhao, Shao-Long Zhong, Chenyi Yi, Liangti Qu, Zhi-Min Dang*. A high-response-frequency bimodal network polyacrylate elastomer with ultrahigh power density under low electric field. Nature Communications, 2024, 15, 9819.

[5]Jia-Yao Pei, Shao-Long Zhong, Yu Zhao, Li-Juan Yin, Qi-Kun Feng, Lei-Huang, Di-Fan Liu, Yong-Xin Zhang, Zhi-Min Dang*. All-organic dielectric polymer films exhibiting superior electric breakdown strength and disc harged energy density by adjusting electrode-dielectric interface with organic nano-interlayer. Energy & Environmental Science, 2021, 14, 5513-5522.

[6]Minhao Yang*, Yanlong Zhao, Zepeng Wang, Huarui Yan, Zeren Liu, Qi Li*, Zhi-Min Dang*. Surface ion-activated polymer composite dielectrics for superior high-temperature capacitive energy storage. Energy & Enviro nmental Science, 2024, 17(4), 1592-1602.

[7]Xiaorong Dou, Zheqi Chen, Fuhao Ren, Lijun He, Jianxiong Chen, Li-Juan Yin, Yingwu Luo*, Zhi-Min Dang*, Jie Mao*. Dielectric elastomer network with large side groups achieves large electroactive deformation for s oft robotic grippers. Advanced Functional Materials, 2024, 34(44), 2407049.

[8]Minhao Yang*, Zepeng Wang, Yanlong Zhao, Zere Liu, Hui Pang, Zhi-Min Dang*. Unifying and suppressing conduction losses of polymer dielectrics for superior high-temperature capacitive energy storage. Advanced Ma terials, 2024, 36(52), 2309640.

[9]Zhou WY*, Cao GZ, Yuan MX*, Zhong SL, Wang YD, Liu XG, Cao D, Peng WW, Liu J, Wang GH, Dang ZM*, Li B*. Core–Shell Engineering of Conductive Fillers toward Enhanced Dielectric Properties: A Universal P olarization Mechanism in Polymer Conductor Composites. Advanced Materials, 2023, 35(2), 2207829.

[10]Wan BQ, Dong XD, Yang X, Wang JQ, Zheng MS, Dang ZM, Chen G, Zha JW*. Rising of Dynamic Polyimide Materials: A Versatile Dielectric for Electrical and Electronic Applications. Advanced Materials, 2023, 35, 2 301185.

[11]Wan BQ, Xiao MY, Dong XD, Yang X, Zheng MS, Dang ZM*, Chen G, Zha JW*. Dynamic Covalent Adaptable Polyimide Hybrid Dielectric Films with Superior Recyclability. Advanced Materials, 2023, 35, 2304175.

[12]Zhu TG, Zhao H*, Zhang N, Zhang CY, Yin L, Dang ZM*, Bai JB*. Ultrahigh Energy Storage Density in Poly(vinylidene fluoride)-Based Composite Dielectrics via Constructing the Electric Potential Well. Advanced En ergy Materials, 2023, 2203587.

[13]Zepeng Wang, Yanlong Zhao, Minhao Yang*, Huarui Yan, Chao Xu*, Bobo Tian*, Chong Zhang, Qing Xie, Zhi-Min Dang*. Surface strengthening of polymer composite dielectrics for superior high-temperature capacitiv e energy storage. Advanced Energy Materials, 2025, 2405411.

[14]Wenying Zhou*, Ting Li, Mengyue Yuan*, Bo Li*, Shaolong Zhong, Zhen Li, Xiangrong Liu, Juanjuan Zhou, Yun Wang, Huiwu Cai, Zhi-Min Dang*. Decoupling of inter-particle polarization and intra-particle polarizati on in core-shell structured nanocomposites towards improved dielectric performance. Energy Storage Materials, 2021, 42, 1-11.

[15]Biao Liu, Minhao Yang*, Wen-Ying Zhou, Hui-Wu Cai*, Shao-Long Zhong, Ming-Sheng Zheng, Zhi-Min Dang*. High energy density and discharge efficiency polypropylene nanocomposites for potential high-power ca pacitor. Energy Storage Materials, 2020, 27, 443-452.

[16]Zhi-Min Dang*, Tao Zhou, Sheng-Hong Yao, Jin-Kai Yuan, Jun-Wei Zha, Hong-Tao Song, Jian-Ying Li, Qiang Chen, Wan-Tai Yang, Jinbo Bai. Advanced Calcium Copper Titanate/Polyimide hybrid films with high diele ctric permittivity. Advanced Materials, 2009, 21, 2077-2082.

[17]Zhi-Min Dang*, Lan Wang, Yi Yin, Qing Zhang, Qing-Quan Lei. Giant dielectric permittivities in functionalized carbon-nanotube/electroactive-polymer nanocomposites. Advanced Materials, 2007, 19, 852-857.

[18]Zhi-Min Dang*, You-Qin Lin, Hai-Ping Xu, Chang-Yong Shi, Sheng-Tao Li, Jinbo Bai. Fabrication and Dielectric Characterization of Advanced BaTiO3/polyimide nanocomposite films. Advanced Functional Materials, 2 008, 18, 1509-1517.

[19]Zhi-Min Dang, Y.-H. Lin, C.-W. Nan*. Novel Ferroelectric Polymer-matrix Composites with a High Dielectric Constant at the Percolation Threshold. Advanced Materials, 2003, 15(19), 1625-1629.

[20]Yi-He Zhang*, Sheng-Guo Lu,Yuan-Qing Li,Zhi-Min Dang, John H. Xin, Shao-Yun Fu, Guang-Tao Li, Rui-Rong Guo, Lai-Feng Li. Novel Silica Tube/Polyimide Composite Films with Variable Low Dielectric Constant. Advanced Materials, 2005, 17(8), 1056-1058.

[21]Yu Yang, Zhan-Sheng Gao, Minhao Yang, Ming-Sheng Zheng*, Dong-Rui Wang, Jun-Wei Zha, Yong-Qiang Wen, Zhi-Min Dang*. Enhanced energy conversion efficiency in the surface modified BaTiO3 nanoparticles/po l yurethane nanocomposites for potential dielectric elastomer generators. Nano Energy, 2019, 59, 363-371.

[22]Yue Zhang, Changhai Zhang , Yu Fenga, Tiandong Zhang*, Qingguo Chena, Qingguo Chi*, Lizhu Liua, Guofeng Li, Yang Cuia, Xuan Wang, Zhi-Min Dang*, Qingquan Lei. Excellent energy storage performance and the rmal property of polymerbased composite induced by multifunctional one-dimensional nanofibers oriented in-plane direction. Nano Energy, 2019, 56, 138-150.

[23]Ming-Sheng Zheng, Yu-Ting Zheng, Jun-Wei Zha*, Yu Yang, Peng Han, Yong-Qiang Wen, Zhi-Min Dang*. Improved dielectric, tensile and energy storage properties of surface rubberized BaTiO3/polypropylene nanoco mposites. Nano Energy, 2018, 48, 144-151.

IEEE Transactions期刊类

[1]Zhi-Yuan Wu, Ze Wang, Jing-Zhou Liu, Shao-Long Zhong, Jian-Tao Wang, Lei Huang, Zhi-Min Dang*, Wei Wang. Study on the structure-function relationship between metallized layer and self-healing morphology in metallized film. IEEE Transactions on Plasma Science, 2024, 52(11), 5366-5375.

[2]Dayong Zheng, Geye Lu, Zhiyuan Wang, Juntao Wang, Zhi-Min Dang, Yongchang Zhang, Pinjia Zhang*. The effect of bearing impedance on online condition monitoring for rotor winding insulation of doubly-fed indu ction generator. IEEE Transactions on Power Electronics, 2024, 39(9), 11697-11707.

[3] Jun-Wei Zha*, Qing-Qing Qin, Zhi-Min Dang. Effect of Multi-Dimensional Zinc Oxide on Electrical Properties of Polypropylene Nanocomposites for HVDC Cables. IEEE Transactions on Dielectrics and Electrical Insula tion, 2019, 26, 868-875.

[4] Shao-Long Zhong, Jun-Wei Zha, Zhi-Min Dang*. Prediction on Effective Permittivity of 0-3 Connectivity Particle/Polymer Composites at Low Concentration with Finite Element Method. IEEE Transactions on Dielectric sand Electrical Insulation, 2018, 25(6), 2122-2128.

[5] Jun-Wei Zha*, Jun-Fu Wang, Si-Jiao Wang, Qing-Qing Qin, Zhi-Min Dang. Effect of Modified ZnO on Electrical Properties of PP/SEBS Nanocomposites for HVDC Cables. IEEE Transactions on Dielectrics and Electrica lInsulation, 2018, 25(6), 2358-2365.

[6] Jun-Wei Zha*, Hong-Da Yan, Wei-Kang Li, Zhi-Min Dang. Environmentally Friendly Polypropylene/Thermoplastic Elastomer Composites with Modified Graphene Oxide for HVDC Application. IEEE Transactions on Di electrics and Electrical Insulation, 2018, 25(3), 1088-1094.

[7] Chong Zhang, Jun-Wei Zha*, Hong-Da Yan, Wei-Kang Li, Yong-Qiang Wen, Zhi-Min Dang. Effects of trap density on space charge suppression of block polypropylene/Al2O3 composite under high temperature. IEEE Tra nsactions on Dielectrics and Electrical Insulation, 2018, 25(4), 1293-1299.

[8] Xiang-Yu Li, Jun-Wei Zha, Si-Jiao Wang, Shao-Long Zhong, Chong Zhang, Zhi-Min Dang*. Effect of High-Thermal Conductivity Epoxy Resin on Heat Dissipation Performance of Saturated Reactor. IEEE Transactions o n Dielectrics and Electrical Insulation, 2017, 24(6), 3898-3905.

[9] Si-Jiao Wang, Jun-Wei Zha, Wei-Kang Li, Dong-Li Zhang, Zhi-Min Dang*. Sandwiched Structure Effect on Space Charge Characteristics of Alumina/Polyethylene Nanocomposites. IEEE Transactions on Dielectrics and Electrical Insulation, 2017, 24, 1365-1371.

[10] Jun-Wei Zha*, Ying Wang, Wei-Kang Li, Si-Jiao Wang, Zhi-Min Dang. Electrical Properties of Polypropylene/Styrene-Ethylene-Butylene-Styrene Block Copolymer/MgO Nanocomposites. IEEE Transactions on Dielectr ics and Electrical Insulation, 2017, 24, 1457-1464.

[11] Zhi-Hui Yang, Peng-Hao Hu, Si-Jiao Wang, Jun-Wei Zha, Zhi-Chong Guo, Zhi-Min Dang*. Effect of Nano-fillers Distribution on the Nonlinear Conductivity and Space Charge Behavior in SiC/PDMS Composites. IEEE Transactions on Dielectrics and Electrical Insulation, 2017, 24, 1735-1742.

[12] Jun-Wei Zha, Qian Liu, Zhi-Min Dang*, George Chen. Tailored Wide-frequency Dielectric Behavior of Polyimide Composite Films with BaxSr1-xTiO3 Perovskites Ceramic Particles. IEEE Transactions on Dielectrics a nd Electrical Insulation, 2016, 23(4), 2337-2343.

[13] Jun-Wei Zha*, Yun-Hui Wu, Si-Jiao Wang, Dong-Hong Wu, Hong-Da Yan, Zhi-Min Dang*. Improvement of Space Charge Suppression of Polypropylene for Potential Application in HVDC Cables. IEEE Transactions on Dielectrics and Electrical Insulation, 2016, 23(1), 113-120.

[14] Si-Jiao Wang, Jun-Wei Zha, Yun-Hui Wu, Li Ren, Ji Wu, Zhi-Min Dang*. Preparation, Microstructure and Properties of Polyethylene/Alumina nanocomposites for HVDC insulation. IEEE Transactions on Dielectrics and Electrical Insulation, 2015, 22(6), 3350-3356.

[15] Zhi-Min Dang*, Yue Yu, Jun-Wei Zha, Tao Zhou, Hong-Tao Song, Sheng-Tao Li. Microstructure and Dielectric Characterization of Micro-Nanosize Cofilled Composite Films with High Dielectric Permittivity. IEEE Tra nsactions on Dielectrics and Electrical Insulation, 2011, 18(5), 1518-1525.

[16] Dongrui Wang, Meiyan Huang, Jun-Wei Zha, Jun Zhao, Zhi-Min Dang*, Zhongyang Cheng. Dielectric Properties of Polystyrene Based Composites Filled with Core-Shell BaTiO3/Polystyrene Hybrid Nanoparticles. IEE E Transactions on Dielectrics and Electrical Insulation, 2014, 21, 1438-1445.

[17] Jun-Wei Zha, Wei-kang Li, Yan-Hui Zhu, Zhi-Min Dang*, George Chen. Effect of Micro-Si3N4–nano-Al2O3 cofilled Particles on Thermal Conductivity, Dielectric and Mechanical Properties of Silicone Rubber Compos ites. IEEE Transactions on Dielectrics and Electrical Insulation, 2014, 21, 1989-1996.

[18] Jun-Wei Zha, Zhi-Min Dang*, Kai Zhao, Xiao-Quan Zheng, Sheng-Tao Li. Prominent nonlinear electrical conduction characteristic in T-ZnOw/PTFE composites with low threshold field. IEEE Transactions on Dielectric s and Electrical Insulation, 2012, 19(2), 567-573.

[19] Jun-Wei Zha, Zhi-Min Dang*, Tai Yang, Tao Zhou, Hong-Tao Song, Sheng-Tao Li. Advanced dielectric properties of BaTiO3/polyvinylidene-fluoride nanocomposites with sandwich multi-layer structure. IEEE Transacti ons on Dielectrics and Electrical Insulation, 2012, 19, 1312-1317.

[20] Hong-Tao Song, Zhi-Min Dang*, Jing Lv, Sheng-Hong Yao, Jun-Wei Zha, Yi Yin. Enhanced Electrical Properies in percolative Low-density polyethylene/Carbon Nanotubes Nanocomposites. IEEE Transactions on Diele ctrics and Electrical Insulation, 2010, 17(3), 645-652.

授权专利

1. 党智敏，冯启琨，张涌新,王昕劼,戴熙瀛,邢照亮,张翀,嵇建飞,齐贝贝,陈静. 电介质复合材料及其制备方法、电介质薄膜及其制备方法和应用. 授权年份2024年，专利号ZL202310147554.3

2. 党智敏，冯启琨. P(VDF-HFP)/PI复合材料及其制备方法和应用. 授权年份2023年，专利号ZL202210534652.8

3. 党智敏，冯启琨，钟少龙，裴家耀，张涌新. 全有机复合材料薄膜及其制备方法与应用. 授权年份2023，专利号ZL202111627110.7

4. 党智敏，冯启琨，宋延晖，张涌新. 环氧树脂基复合材料及其制备方法. 授权年份2023年，专利号ZL202111627076.3

5. 党智敏，裴家耀，尹丽娟. 高温储能聚合物电介质及其制备方法和应用. 授权年份2022年，专利号ZL202210286641.2.

6. 党智敏，尹丽娟，裴家耀，钟少龙，张冬丽. 一种丙烯酸酯介电弹性体及其制备方法. 授权年份2021年，专利号ZL202011285609.X.

7. 党智敏，张冬丽，王思蛟. 环氧树脂复合材料及其制备方法. 授权年份2021年，专利号ZL202010824049.4.

8. 党智敏, 郑明胜. 一种介电薄膜及其制备方法和薄膜电容器. 授权年份2021年，专利号 ZL202010199151.X.

9. 党智敏. 以橡胶组份添加制备高击穿和高储能密度复合材料薄膜的方法. 授权年份2021年，专利号 ZL201710928035.5.

10. 党智敏, 宋红黎. 一种适于低温烘干超薄膜的高速连续化涂布设备. 授权年份2021年，专利号ZL202022637010.X.

11. 党智敏，郑明胜，张翀，邢照亮，戴熙瀛，张翔宇. 一种复合材料及其制备方法和应用. 授权年份2021年，专利号ZL202010199051.7.

12. 党智敏. 一种三明治结构高储能密度聚合物基介电复合材料及制备方法. 授权年份2020年，专利号ZL201710928412.5.

13. 查俊伟，李贞，党智敏. 一种具有驻极体效应的丝素蛋白纤维膜及其应用. 授权年份2020年，专利号ZL201810623865.1.

14. 查俊伟，黄娜，党智敏. 一种三层结构的全固态聚合物电解质膜的制备方法. 授权年份2019年，专利号ZL201510958722.2.

15. 王东瑞，马冬敏，刘妹静，党智敏. 一种阳离子聚电解质的制造方法及在超级电容器中的应用. 授权年份2018年，专利号ZL201510441347.4.

16. 党智敏，梁涛，查俊伟. 一种基于超长碲微米线的柔性应变传感器. 授权年份2017年，专利号ZL201410313150.8.

17. 党智敏，闫轰达，查俊伟. 可回收聚丙烯/SEBS/氧化石墨烯电缆料的制备方法. 授权年份2017年，专利号ZL201510930915.7.

18. 党智敏，张玲，王东瑞. 一种充气预形变的电机械性能测试装置及测试方法. 授权年份2016年，专利号ZL201410373009.7.

19. 党智敏，周涛，查俊伟. 一种含有改性石墨烯高介电常数三相复合材料及制备方法. 授权年份2014年，专利号ZL201210145040.6.

20. 党智敏，白晓飞，查俊伟. 一种埋入式电容器及其制备方法. 授权年份2014年，专利号ZL201210163953.0.

21. 党智敏，赵航，查俊伟. 一种高驱动敏感度硅橡胶基介电弹性体复合材料及其制备方法. 授权年份2013年，专利号ZL201210163387.3.

22. 党智敏，喻玥. 一种微纳共填充高介电常数柔性复合薄膜的制备. 授权年份2013年，专利号ZL201010123331.6.

23. 党智敏，孟兴，查俊伟，周涛. 高储能聚合物纳米管电容器阵列的制备方法. 授权年份2013年，专利号ZL201210153626.7.

24. 党智敏，李维康. 一种高PTC强度和稳定性的聚合物基复合材料及其制备方法. 授权年份2012年，专利号ZL201010177645.4.

25. 谢丹，武潇，任天令，党智敏. 聚合物复合材嵌入式微电容及其制备方法. 授权年份2012年，专利号ZL201010232566.9.

26. 党智敏，杨泰，查俊伟. 一种多层结构的聚合物基电介质复合材料及其制备方法. 授权年份2011年，专利号ZL200910083691.5.

27. 南策文，党智敏，沈洋. 高介电常数的三元复合材料及其制备方法. 授权年份2007年，专利号ZL02131239.7.

28. 南策文，党智敏，沈洋. 含有碳纳米管的高介电复合材料及其制备方法. 授权年份2005年，专利号ZL03104776.9.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

学术组织任职

1. IEEE，Senior Member

2. IET，Fellow

3. 中国科协先进材料联合体 委员

4. 中国复合材料学会 常务理事

5. 中国复合材料学会介电高分子复合材料与应用专委会 主任委员

6. 中国复合材料学会纳米复合材料分会 副主任委员

7. 中国复合材料学会矿物复合材料专委会 副主任委员

8. 中国仪表功能材料学会电子元器件关键材料与技术专委会 副主任委员

9.中国电工技术学会工程电介质专委会 委员

10.中国电工技术学会储能系统专委会 委员

11.中国电工技术学会电力电容器专委会 委员

12.中国电工技术学会绝缘材料与绝缘技术专委会 委员

13.中国电机工程学会高电压技术专委会 委员

14.中国兵工学会燃烧与爆轰控制专委会 委员

15.北京电子学会材料电磁测量专委会 主任委员

16.陕西省高分子科学与技术重点实验室学术委员会 副主任委员

17.西安市新能源材料化学重点实验室学术委员会 委员

18.先进输电技术国家重点实验室学术委员会 委员

国内外期刊编委

1. IET Nanodielectrics，期刊发起人和主编 (Sponsor and Editor-in-Chief)

2. Journal of Materiomics, 国际编委 (Editorial Board Member)

3. Journal of Advanced Dielectrics, 国际编委 (Editorial Board Member)

4. Journal of Advanced Physics, 亚洲区主编 (Asian Editor)

5. 《复合材料学报》编委

6. 《功能材料》编委

7. 《绝缘材料》编委

8. 《电力电容器与无功补偿》编委

9. 《高压电器》编委