個(gè)人詳情

張齊艷，男，博士，深圳大學(xué)電子與信息工程學(xué)院助理教授，特聘研究員。入選廣東省科協(xié)青年科技人才，深圳市優(yōu)秀科技創(chuàng)新人才，深圳市海外高層次人才，深龍英才。2015年本科畢業(yè)于四川大學(xué)，2020年在清華大學(xué)取得博士學(xué)位，2018-2019在美國(guó)賓夕法尼亞州立大學(xué)電子工程系進(jìn)行國(guó)家公派訪學(xué)，2020-2022年在華為技術(shù)有限公司2012實(shí)驗(yàn)室任高級(jí)工程師。以第一作者或通訊作者在Nature Communications、Matter、Energy & Environment Science、Nano Letters等知名期刊發(fā)表SCI收錄論文20余篇，申請(qǐng)發(fā)明專(zhuān)利10余項(xiàng)（含PCT專(zhuān)利3項(xiàng)），主持國(guó)家、省、市等縱向科研項(xiàng)目及企業(yè)委托橫向項(xiàng)目共10余項(xiàng)，參與重大科技計(jì)劃項(xiàng)目3項(xiàng)。曾獲得深圳大學(xué)優(yōu)秀本科教師獎(jiǎng)、深圳大學(xué)百篇優(yōu)秀本科畢業(yè)論文指導(dǎo)教師、華為明日之星獎(jiǎng)、華為部長(zhǎng)獎(jiǎng)、清華大學(xué)優(yōu)秀博士學(xué)位論文獎(jiǎng)、北京市優(yōu)秀畢業(yè)生等多項(xiàng)榮譽(yù)獎(jiǎng)勵(lì)。

E-mail: zhangqy@szu.edu.cn

辦公室：致真樓L6-1605

工作經(jīng)歷

2022/07-至今，深圳大學(xué)，電子與信息工程學(xué)院，助理教授，特聘研究員

2020/06-2022/06，華為技術(shù)有限公司，2012實(shí)驗(yàn)室，高級(jí)工程師A

教育經(jīng)歷

2015/09-2020/06 清華大學(xué)，工學(xué)博士

2018/09-2019/09 美國(guó)賓夕法尼亞州立大學(xué)，訪問(wèn)學(xué)者

2018/02-2018/03 韓國(guó)科學(xué)技術(shù)院，交換生

2011/09-2015/06 四川大學(xué)，工學(xué)學(xué)士

研究方向

先進(jìn)封裝工藝與材料、柔性電子材料與器件、薄膜電容器電介質(zhì)、鐵電聚合物與器件、高頻低損耗電介質(zhì)、高耐壓絕緣技術(shù)等。

招生方向

電子科學(xué)與技術(shù)（學(xué)術(shù)型）

集成電路科學(xué)與工程（學(xué)術(shù)型）

集成電路工程（專(zhuān)業(yè)型）

科研項(xiàng)目

（一）主持

1.國(guó)家自然科學(xué)基金面上項(xiàng)目，主持，2026.01-2029.12.

2.國(guó)家自然科學(xué)基金青年科學(xué)基金項(xiàng)目，主持，2022/09/08-2025/12/31。

3.軍委裝備發(fā)展部裝備重大基礎(chǔ)研究項(xiàng)目，主持，2025/02-2025/10。

4.廣東省自然科學(xué)基金面上項(xiàng)目，主持，2026/01-2028/12。

5.廣東省普通高校特色創(chuàng)新項(xiàng)目（自然科學(xué)），主持，2025/10-207/10。

6.廣東省科協(xié)青年科技人才培育計(jì)劃，主持，2025/01-2026/12。

7.深圳市優(yōu)秀科技創(chuàng)新人才培養(yǎng)項(xiàng)目，主持，2023/04/01-2025/04/01。

8.深圳市基礎(chǔ)研究（自然科學(xué)基金）面上項(xiàng)目，主持，2024/11/27-2027/11/26。

9.深圳市海外高層次人才科研啟動(dòng)項(xiàng)目，主持，2023/01/01-2025/12/31。

10.深圳大學(xué)青年教師科研啟動(dòng)項(xiàng)目，主持，2023/11/01-2025/06/01。

11.航天一院委托科技項(xiàng)目，主持，2025/01-2025/12。

12.集成電路材料全國(guó)重點(diǎn)實(shí)驗(yàn)室開(kāi)放課題，主持，2025/07/01-2027/06/30。

13.電工材料電氣絕緣全國(guó)重點(diǎn)實(shí)驗(yàn)室開(kāi)放課題，主持，2025/02/28-2026/12/31。

14.廣東省重點(diǎn)實(shí)驗(yàn)室開(kāi)放課題，主持，2024/09/25-2026/05/31。

（二）參與

15.深圳市技術(shù)攻關(guān)重點(diǎn)項(xiàng)目，重2021N029 5G+高頻PCB板材及基礎(chǔ)材料關(guān)鍵技術(shù)研發(fā)，800萬(wàn)，參與，2022/01-2024/12。

16.深圳市半導(dǎo)體異質(zhì)集成技術(shù)重點(diǎn)實(shí)驗(yàn)室（籌建啟動(dòng)），500萬(wàn)，參與，2023/03/2025/03。

17.深圳市先進(jìn)射頻封裝公共服務(wù)平臺(tái)組建項(xiàng)目，15000萬(wàn)，參與，2024/04-2025/07。

18.深圳大學(xué)-華源智信聯(lián)合研究所合作協(xié)議，500萬(wàn)，參與，2024/05/07-2026/04/30。

文章發(fā)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

合作發(fā)表論文

[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.

發(fā)明專(zhuān)利

[1] 張齊艷; 陳昊; 黃雙武；二胺單體交聯(lián)改性含氟鐵電聚合物、制備方法及器件，2024-12-03，中國(guó)，CN202411758583.4。

[2] 張齊艷; 謝巧輝; 黃雙武；一種具有自組裝納米尺度多界面的全聚合物納米結(jié)構(gòu)電介質(zhì)薄膜及其制備方法，2024-10-25，中國(guó)，CN2024115017757。

[3] 張齊艷; 謝巧輝; 黃雙武；雙馬來(lái)酰亞胺基熱固性電介質(zhì)薄膜及其制備方法、電容器，2023-8-7，中國(guó)，CN202310993370.9。

[4] 張齊艷; 謝巧輝; 黃雙武；半互穿網(wǎng)絡(luò)聚合物、復(fù)合材料、電介質(zhì)薄膜及其制備方法，2023-12-6，中國(guó)，CN202311665378.9。

[5] 張齊艷; 任雪; 黃雙武；聚苯醚基復(fù)合材料及其制備方法、天線基板和饋電天線，2023-09-11，中國(guó)，CN202311170018.1。

[6] 張齊艷; 林仁藩; 黃雙武；一種摻雜含氟鐵電聚合物、薄膜及其制備方法和應(yīng)用，2023-7-16，中國(guó)，CN2024109486729。

[7] 張齊艷; 田清山; 陶偉；一種印刷電路板及其制作方法，2022-08-23，中國(guó)，CN202211014121.2。

[8] 張齊艷; 蔡黎; 高峰；一種導(dǎo)熱材料及其制作方法、半固化片、層壓板、電路板，2021-3-31，中國(guó)，CN202110352474.2。

[9] 張齊艷；蔡黎；高峰；復(fù)合銅箔結(jié)構(gòu)、其制備方法及覆銅箔層壓板和印刷電路板，2021-8-31，中國(guó)，CN202111009822 .2。

[10] 張齊艷；譚莉；李澤；李婷；一種二酐單體及其合成的聚酰亞胺，2025-11-04，中國(guó)，CN2025115986647。

PCT專(zhuān)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.