个人详情

张齐艳，男，博士，深圳大学电子与信息工程学院助理教授，特聘研究员。入选广东省科协青年科技人才，深圳市优秀科技创新人才，深圳市海外高层次人才，深龙英才。2015年本科毕业于四川大学，2020年在清华大学取得博士学位，2018-2019在美国宾夕法尼亚州立大学电子工程系进行国家公派访学，2020-2022年在华为技术有限公司2012实验室任高级工程师。以第一作者或通讯作者在Nature Communications、Matter、Energy & Environment Science、Nano Letters等知名期刊发表SCI收录论文20余篇，申请发明专利10余项（含PCT专利3项），主持国家、省、市等纵向科研项目及企业委托横向项目共10余项，参与重大科技计划项目3项。曾获得深圳大学优秀本科教师奖、深圳大学百篇优秀本科毕业论文指导教师、华为明日之星奖、华为部长奖、清华大学优秀博士学位论文奖、北京市优秀毕业生等多项荣誉奖励。

E-mail: zhangqy@szu.edu.cn

办公室：致真楼L6-1605

工作经历

2022/07-至今，深圳大学，电子与信息工程学院，助理教授，特聘研究员

2020/06-2022/06，华为技术有限公司，2012实验室，高级工程师A

教育经历

2015/09-2020/06 清华大学，工学博士

2018/09-2019/09 美国宾夕法尼亚州立大学，访问学者

2018/02-2018/03 韩国科学技术院，交换生

2011/09-2015/06 四川大学，工学学士

研究方向

先进封装工艺与材料、柔性电子材料与器件、薄膜电容器电介质、铁电聚合物与器件、高频低损耗电介质、高耐压绝缘技术等。

招生方向

电子科学与技术（学术型）

集成电路科学与工程（学术型）

集成电路工程（专业型）

科研项目

（一）主持

1.国家自然科学基金面上项目，主持，2026.01-2029.12.

2.国家自然科学基金青年科学基金项目，主持，2022/09/08-2025/12/31。

3.军委装备发展部装备重大基础研究项目，主持，2025/02-2025/10。

4.广东省自然科学基金面上项目，主持，2026/01-2028/12。

5.广东省普通高校特色创新项目（自然科学），主持，2025/10-207/10。

6.广东省科协青年科技人才培育计划，主持，2025/01-2026/12。

7.深圳市优秀科技创新人才培养项目，主持，2023/04/01-2025/04/01。

8.深圳市基础研究（自然科学基金）面上项目，主持，2024/11/27-2027/11/26。

9.深圳市海外高层次人才科研启动项目，主持，2023/01/01-2025/12/31。

10.深圳大学青年教师科研启动项目，主持，2023/11/01-2025/06/01。

11.航天一院委托科技项目，主持，2025/01-2025/12。

12.集成电路材料全国重点实验室开放课题，主持，2025/07/01-2027/06/30。

13.电工材料电气绝缘全国重点实验室开放课题，主持，2025/02/28-2026/12/31。

14.广东省重点实验室开放课题，主持，2024/09/25-2026/05/31。

（二）参与

15.深圳市技术攻关重点项目，重2021N029 5G+高频PCB板材及基础材料关键技术研发，800万，参与，2022/01-2024/12。

16.深圳市半导体异质集成技术重点实验室（筹建启动），500万，参与，2023/03/2025/03。

17.深圳市先进射频封装公共服务平台组建项目，15000万，参与，2024/04-2025/07。

18.深圳大学-华源智信联合研究所合作协议，500万，参与，2024/05/07-2026/04/30。

文章发表

[1]Qiyan Zhang*, Qiaohui Xie, Tao Wang, Shuangwu Huang*, Q.M. Zhang*, Scalable all polymer dielectrics with self-assembled nanoscale multiboundary exhibiting superior high temperature capacitive performance, Nature Communications, 2024, 15: 9351.

[2]Qiyan Zhang*, Dongmou Li, Yueqi Zhong, Yuna Hu, Shuangwu Huang*, Shuxiang Dong, Qiming Zhang*. Low-entropy Amorphous Dielectric Polymers for High-Temperature Capacitive Energy Storage. Energy & Environmental Science, 2024, 17: 8119-8126.

[3]Qiaohui Xie, Wugang Liao, Weiping Gong, Chenghuan Huang, Shuangwu Huang, Qiyan Zhang*. Nanostructure Engineering Significantly Enhances Capacitive Energy Storage Performance in All-Polymer Dielectrics at Elevated Temperatures, Nano Letters, 2025, 25: 7793-7800.

[4]Minghao Lin, Juntian Zhuo, Shuangwu Huang Qiyan Zhang*, Q.M. Zhang, Sandwich-structured polymer dielectrics exhibiting significantly improved capacitive performance at high temperatures by roll-to-roll physical vapor deposition, Chemical Engineering Journal, 2024, 498: 155586.

[5]Jinbao Chen, Ting Li, Ziyu Lv, Yongbiao Zhai; Wugang Liao, Qiyan Zhang*. Enhancement of high-temperature capacitive energy storage performance in all-polymer dielectric composites via microphase separation. Applied Physics Letters, 2025, 127, 012903.

[6]Dongmou Li, Shuangwu Huang, Weiping Gong, Shuxiang Dong, Qiyan Zhang*. Suppressing Conduction Losses and Enhancing High-Temperature Capacitive Energy Storage Performance in Polymer Dielectrics through Maleic Anhydride Grafting at 200°C. The Journal of Physical Chemistry Letters, 2025, 16: 6757-6764.

[7]Renfan Lin, Shuangwu Huang, Weiping Gong, Qiyan Zhang^*, Q.M. Zhang. Enhanced Breakdown Strength and Reduced Polarization Hysteresis in Relaxor Ferroelectric Polymers with Increased Gamma Phase Content for Energy Storage Capacitors. Applied Physics Letters, 2025, 126: 042902.

[8]Hao Chen, Ding Ai, Wandong Li, Ziyu Lv, Yongbiao Zhai, Shuangwu Huanga, Qiyan Zhang*. Rigid short-chain cross-linking networks for high energy density and improved charge–discharge efficiency in fluoropolymer ferroelectrics. Journal of Materials Chemistry C, 2025, 13, 20013-20020.

[9]Qiyan Zhang*, Juntian Zhuo, Wugang Liao, Shuangwu Huang*, Shuxiang Dong. Molecular Trap Engineering Enables Superior High-Temperature Charge-Discharge Efficiency in a Polymer Blend with Densely Packed Molecular Chains. Journal of Materials Chemistry C, 2025,13, 5496-5502.

[10]Juntian Zhuo, Minghao Lin, Qiyan Zhang*, Shuangwu Huang. Design, fabrication, and high-temperature dielectric energy storage performance of thermoplastic polyimide / aluminum oxide sandwich-structured flexible dielectric films. Acta Phys. Sin., 2024, 17: 177701.

2022年及以前

[11]Xin Chen^†, Qiyan Zhang^†, Ziyu Liu, Yifei Sun, Q. M. Zhang. High dielectric response in dilute nanocomposites via hierarchical tailored polymer nanostructures. Appl. Phys. Lett., 2022, 120: 162902.

[12]Qiyan Zhang†, Xin Chen†, Bing Zhang†, Tian Zhang, Wengchang Lu, Zhe Chen, J. Bernholc, Q. M. Zhang*. High-temperature polymers with record-high breakdown strength enabled by rationally designed chain-packing behavior. Matter, 2021, 4(7): 2448-2459.

[13]Qiyan Zhang, Bo-Yuan Zhang, Bao-Hua Guo, Zhao-Xia Guo*, Jian Yu*. High-temperature polymer conductors with self-assembled conductive pathways. Composites Part B: engineering, 2020, 192:107989.

[14]Qiyan Zhang, Hansong Li, Bao-Hua Guo, Zhao-Xia Guo*, Jian Yu*. Facile preparation of electromagnetic interference shielding materials enabled by constructing interconnected network of Multi-walled carbon nanotubes in miscible polymeric blend. Chinese J. Polym. Sci., 2020, 38: 593-598.

[15]Qiyan Zhang*, Xin Chen, Tian Zhang, Qiming Zhang*. Giant permittivity materials with low dielectric loss over a broad temperature range enabled by weakening intermolecular hydrogen bonds. Nano Energy, 2019,64: 103916.

[16]Qiyan Zhang, Jingxia Wang, Bo-Yuan Zhang, Bao-Hua Guo, Zhao-Xia Guo*, Jian Yu*. Improved electrical conductivity of polymer/carbon black composites by simultaneous dispersion and interaction-induced network assembly. Composites Science and Technology, 2019,179(28): 106-114.

[17]Qiyan Zhang, Jingxia Wang, Bao-Hua Guo, Zhao-Xia Guo*, Jian Yu*. Electrical conductivity of carbon nanotube-filled miscible poly(phenylene oxide)/polystyrene blends prepared by melt compounding. Composites Part B: engineering, 2019,176: 107213.

[18]Qiyan Zhang, Bo-Yuan Zhang, Wei-Jia Wang, Zhao-Xia Guo*, Jian Yu*. Highly efficient electrically conductive networks in carbon-black-filled ternary blends through the formation of thermodynamically induced self-assembled hierarchical structures. Journal of Applied Polymer Science, 2018,135(8): 45877

[19]Qiyan Zhang, Jingxia Wang, Jian Yu*, Zhao-Xia Guo*. Improved electrical conductivity of TPU/carbon black composites by the addition of COPA and selective localization of carbon black at the interface of sea-island structured polymer blend. Soft Matter, 2017,13: 3431-3439.

[20]Qiyan Zhang, Bo-Yuan Zhang, Zhao-Xia Guo*, Jian Yu*. Comparison between the efficiencies of two conductive networks formed in carbon black-filled ternary polymer blends by different hierarchical structures. Polymer Testing, 2017,63: 141-149.

[21]Qiyan Zhang, Bo-Yuan Zhang, Zhao-Xia Guo*, Jian Yu*. Tunable electrical conductivity of carbon-black-filled ternary polymer blends by constructing a hierarchical structure. Polymers, 2017,9(9): 404.

[22]Qiyan Zhang, Hongmei Peng,Jian Kang*, Ya Cao, Ming Xiang. Effects of melt structure on non-isothermal crystallization behavior of isotactic polypropylene nucleated with α/β compounded nucleating agents. Polymer Engineering and Science, 2017, 57(9): 989-997.

[23]Qiyan Zhang, Zhengfang Chen, Bing Wang, Jinyao Chen, Feng Yang, Jian Kang*, Ya Cao*, Ming Xiang, Huilin Li. Effects of melt structure on crystallization behavior of isotactic polypropylene nucleated with α/β compounded nucleating agents. Journal of Applied Polymer Science, 2015,132(4): 41355

合作发表论文

[24]Zezhuang Yi; Zhikai Lin; Yueyang Yao; Yongbiao Zhai; Yan Wang; Qiyan Zhang; Ye Zhou; Ziyu Lv; Su-Ting Han. Peptide-Based Electronics for Neuromorphic Hardware. Advanced Functional Materials, 2025, e17899.

[25]Xiongfeng Wang; Zhenyi Guo; Weiying Zheng; Zhiquan Liu; Tengzhang Liu; Xiaopei Chen; Peimian Cai; Qiyan Zhang; Wugang Liao. Resistive switching behaviors and conduction mechanisms of IGZO/ZnO bilayer heterostructure memristors. APL Materials. 2024, 12: 111105.

[26]Linfei Gao; Ze Zhong; Qiyan Zhang; Xiaohua Li; Xinbo Xiong; Shaojun Chen; Longkou Chen; Huaibao Yan; Anle Zhang; Jiajun Han; Wenrong Zhuang; Feng Qiu; Hsien-Chin Chiu; Shuangwu Huang; Xinke Liu. Stability of GaN HEMT Device Under Static and Dynamic Gate Stress. IEEE Journal of the Electron Devices Society, 2024, 12: 165-169.

[27]Xin Chen, T.N. Yang, Qiyan Zhang, L.Q. Chen, Vid Bobnar, C. Rahn, Q.M. Zhang*. Topological Structure Enhanced Nanostructure of High Temperature Polymer Exhibiting More Than Ten Times Enhancement of Dipolar Response. Nano Energy, 2021, 88(9):106225.

[28]Tian Zhang^†, Xin Chen^†, Yash Thakur, Biao Lu, Qiyan Zhang, James Runt, Qiming Zhang*. A highly scalable dielectric metamaterial with superior capacitor performance over a broad temperature. Science Advances, 2020, 6: eaax6622.

[29]Tian Zhang, Xin Chen, Qiyan Zhang, Qiming Zhang*. Dielectric enhancement over a broad temperature by nanofiller at ultra-low volume content in poly(ether methyl ether urea. Appl. Phys. Lett., 2020, 117: 072905.

[30]Xin Chen; Tian Zhang, Yash Thakur, Qiyan Zhang, Qiming Zhang*. Dielectric polymers and dielectric metamaterials for high-energy capacitors. Advanced Dielectric Materials for Electrostatic Capacitors. IET Digital Library, 2020.

[31]Hansong Li, Qiyan Zhang, Bao-Hua Guo, Zhao-Xia Guo*, Jian Yu*. Conductive nylon-MXD6 composites prepared by melt compounding associated with formation of carbon black-covered PET domains serving as big conductive particles. Polymer, 2019, 182:121809.

发明专利

[1] 张齐艳; 陈昊; 黄双武；二胺单体交联改性含氟铁电聚合物、制备方法及器件，2024-12-03，中国，CN202411758583.4。

[2] 张齐艳; 谢巧辉; 黄双武；一种具有自组装纳米尺度多界面的全聚合物纳米结构电介质薄膜及其制备方法，2024-10-25，中国，CN2024115017757。

[3] 张齐艳; 谢巧辉; 黄双武；双马来酰亚胺基热固性电介质薄膜及其制备方法、电容器，2023-8-7，中国，CN202310993370.9。

[4] 张齐艳; 谢巧辉; 黄双武；半互穿网络聚合物、复合材料、电介质薄膜及其制备方法，2023-12-6，中国，CN202311665378.9。

[5] 张齐艳; 任雪; 黄双武；聚苯醚基复合材料及其制备方法、天线基板和馈电天线，2023-09-11，中国，CN202311170018.1。

[6] 张齐艳; 林仁藩; 黄双武；一种掺杂含氟铁电聚合物、薄膜及其制备方法和应用，2023-7-16，中国，CN2024109486729。

[7] 张齐艳; 田清山; 陶伟；一种印刷电路板及其制作方法，2022-08-23，中国，CN202211014121.2。

[8] 张齐艳; 蔡黎; 高峰；一种导热材料及其制作方法、半固化片、层压板、电路板，2021-3-31，中国，CN202110352474.2。

[9] 张齐艳；蔡黎；高峰；复合铜箔结构、其制备方法及覆铜箔层压板和印刷电路板，2021-8-31，中国，CN202111009822 .2。

[10] 张齐艳；谭莉；李泽；李婷；一种二酐单体及其合成的聚酰亚胺，2025-11-04，中国，CN2025115986647。

PCT专利

  [1] Zhang Qiyan; Cai Li; Gao Feng. Thermally-conductive material and fabrication method therefor, prepreg, laminate, and circuit board. WO2022206509A1.

  [2] Zhang Qiyan; Cai Li; Gao Feng. Composite copper foil structure, preparation method therefor, copper clad laminate, and printed circuit board. WO2023029908A1.

  [3] Zhang Qiyan; Xie Qiaohui; Huang Shuangwu. Bismaleimide-based thermosetting dielectric film and preparation method therefor, and capacitor. WOCN24109566. 2024-08-02.