高导热聚酰亚胺电介质薄膜研究进展

查俊伟; 王帆

doi:10.7498/aps.71.20221398

摘要

电子器件高度薄型化、多功能化和集成化的时代, 不可避免地会导致复合材料内部的热量积累, 严重影响设备的稳定运行和使用寿命, 如何实现电介质材料快速且高效的导热散热已成为影响电子设备发展的关键问题. 传统聚酰亚胺本征导热系数较低, 限制了在电气设备与智能电网等领域中的应用, 发展新型高导热聚酰亚胺电介质薄膜材料成为国内外研究重点. 本文介绍了复合材料的热传导机制, 概述了近年来导热聚酰亚胺薄膜的研究进展与发展现状, 重点讨论了导热填料、界面相容、成型工艺对材料导热系数的影响, 最后结合导热聚酰亚胺复合电介质材料未来发展的需要, 对研究中存在的一些关键科学技术问题进行了总结与展望.

关键词:

Abstract

In the era of highly thin, multi-functional and integrated electronic devices, it will inevitably lead to the heat accumulation inside the composite material, thereby seriously affecting the operation stability and service life of the equipment. How to realize the rapid and efficient heat conduction and heat dissipation of dielectric materials has become a bottleneck problem restricting the further development of electronic devices. The intrinsic thermal conductivity of traditional polyimide is low, which limits its application in electrical equipment, smart grid and other fields. The development of new high thermal conductivity polyimide dielectric film materials has become the focus of research. This paper introduces the thermal conduction mechanism of composite materials, summarizes the research progress and development status of thermally conductive polyimide films in recent years, and focuses on the effects of thermally conductive fillers, interface compatibility, and molding process of the thermal conductivity of materials. Finally, some key scientific and technical issues in the research are summarized and prospected in combination with the future development needs of thermally conductive polyimide composite dielectric materials.

Keywords:

作者及机构信息

查俊伟^1,2,
王帆¹

1.
北京科技大学化学与生物工程学院, 北京　100083

2.
北京科技大学, 北京材料基因工程高精尖创新中心, 北京　100083

通信作者: 查俊伟, zhajw@ustb.edu.cn

基金项目: 国家自然科学基金(批准号: 51977114)资助的课题.

Authors and contacts

Zha Jun-Wei^1,2,
Wang Fan¹

1.
School of Chemistry and Biological Engineering, University of Science and Technology Beijing, Beijing 100083, China

2.
Beijing Advanced Innovation Center for Materials Genome Engineering, University of Science and Technology Beijing, Beijing 100083, China

Corresponding author: Zha Jun-Wei, zhajw@ustb.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 51977114).

文章全文 : translate this paragraph

参考文献

[1]	Song N, Cao D, Luo X, Wang Q, Ding P, Shi L 2020 Compos. Part A 135 105912 Google Scholar
[2]	刘裕芮, 许艳菲 2022 物理学报 71 023601 Google Scholar Liu Y R, Xu Y F 2022 Acta Phys. Sin. 71 023601 Google Scholar
[3]	Lian R, Lei X, Chen Y, Zhang Q 2019 J. Appl. Polym. Sci. 136 47771 Google Scholar
[4]	Govindaraj B, Sarojadevi M 2018 Polym. Adv. Technol. 29 1718 Google Scholar
[5]	刘金刚, 张秀敏, 田付强, 杨士勇 2017 电工技术学报 32 14 Google Scholar Liu J G, Zhang X M, Tian F Q, Yang S Y 2017 Trans. CES. 32 14 Google Scholar
[6]	Gu J W, Lü Z Y, Wu Y L, Guo Y Q, Tian L D, Qiu H, Li W Z, Zhang Q Y 2017 Compos. Part A 94 209 Google Scholar
[7]	杨娜 2016 硕士学位论文 (天津: 河北工业大学) Yang N 2016 M. S. Thesis (Tianjin: Hebei University of Technology) (in Chinese)
[8]	潘东楷, 宗志成, 杨诺 2022 物理学报 71 086302 Google Scholar Pan D K, Zong Z C, Yang N 2022 Acta Phys. Sin. 71 086302 Google Scholar
[9]	高梦岩, 王畅鸥, 贾妍, 翟磊, 莫松, 何民辉, 范琳 2021 绝缘材料 54 1 Gao M Y, Wang C O, Jia Y, Zhai L, Mo S, He M H, Fan L 2021 Insul. Mater. 54 1
[10]	Zhao L H, Wang L, Jin Y F, Ren J W, Wang Z, Jia L C 2022 Compos. Part B 229 109454 Google Scholar
[11]	Zhang L, Deng H, Fu Q 2018 Compos. Commun. 8 74 Google Scholar
[12]	王春博 2020 博士学位论文(吉林: 吉林大学) Wang C B 2020 Ph. D. Dissertation (Jilin: Jilin University) (in Chinese)
[13]	王艳艳 2021 博士学位论文(安徽: 中国科学技术大学) WangY Y 2021 Ph. D. Dissertation (Anhui: University of Science and Technology of China) (in Chinese)
[14]	田付强, 熊雯雯, 夏宇, 杨春 2020 绝缘材料 53 1 Google Scholar Tian F Q, Xiong W W, Xia Y, Yang C 2020 Insul. Mater. 53 1 Google Scholar
[15]	曲可新 2022 硕士学位论文 (哈尔滨: 哈尔滨理工大学) Qu K X 2022 M. S. Thesis (Harbin: Harbin University of Science and Technology) (in Chinese)
[16]	Liu J, Yang R G 2012 Phys. Rev. B 86 104307 Google Scholar
[17]	周文英, 王蕴, 曹国政, 曹丹, 李婷, 张祥林 2021 复合材料学报 38 2038 Google Scholar Zhou W Y, Wang Y, Cao G Z, Cao D, Li T, Zhang X L 2021 Acta Mate. Compos. Sin. 38 2038 Google Scholar
[18]	Guo Y Q, Ruan K P, Shi X T, Yang X T, Gu J W 2020 Compos. Sci. Technol. 193 108134 Google Scholar
[19]	何亭融, 曲绍宁, 尹训茜 2022 绝缘材料 53 12 Google Scholar He T R, Qu S N, Yin X X 2022 Insul. Mater. 53 12 Google Scholar
[20]	Chen H Y, Ginzburg V V, Yang J, Yang Y F, Liu W, Huang Y, Du L B, Chen B 2016 Prog. Polym. Sci. 59 41 Google Scholar
[21]	许星星 2018 硕士学位论文(重庆: 重庆邮电大学) Xu X X 2018 M. S. Thesis (Chongqing: Chongqing University of Posts and Telecommunications) (in Chinese)
[22]	蒋涛, 邬涵, 张群朝, 郝同辉 2019 湖北大学学报(自然科学版) 41 526 Google Scholar Jiang T, Wu H, Zhang Q C, Hao T H 2019 Hubei Univ. (Nat. Sci. Ed. ) 41 526 Google Scholar
[23]	兰生, 李焜, 高新昀 2017 物理学报 66 136801 Google Scholar Lan S, Li K, Gao X Y 2017 Acta Phys. Sin. 66 136801 Google Scholar
[24]	徐京城, 戴思畅, 李昊亮, 杨俊和 2018 新型炭材料 33 213 Google Scholar Xu J C, Dai S C, Li H L, Yang J H 2018 New Carb. Mater. 33 213 Google Scholar
[25]	Wang X S, Zhao T, Wang Y H, Zhang L, Zou L, Zhang Y T 2022 Comput. Mater. Sci. 210 111051 Google Scholar
[26]	Zhu M X, Song H G, Yu Q C, Chen J M, Zhang H Y 2020 Int. J. Heat. Mass. Tran. 162 120381 Google Scholar
[27]	Guo Y Q, Wang S S, Ruan K P, Zhang H T, Gu J W 2021 Npj Flex. Elec. 5 16 Google Scholar
[28]	Ding D L, Zou M H, Wang X, Qin G Z, Zhang S Y, Chan S Y, Meng Q Y, Liu Z G, Zhang Q Y, Chen Y H 2022 Chem. Eng. J. 437 135438 Google Scholar
[29]	Wu S, Kondo Y, Kakimoto M, et al. 2019 NPJ Comput. Mater. 5 66 Google Scholar
[30]	张萌萌, 贾广跃, 熊丽萍, 何忠义, 晏金灿, 纪红兵 2020 精细化工 37 1081 Google Scholar Zhang M M, Jia G Y, Xiong L P, He Z Y, Yan J C, Ji H B 2020 Fine Chem. 37 1081 Google Scholar
[31]	Zhu C Y, Yang W X, Xu H B, Ding B, Gong L, Li Z Y 2021 Int. J. Therm. Sci. 168 107088 Google Scholar
[32]	Dong M J, Hou G Y, Zhang J C, Liu Li, Liang G Y, Hao X M, Guo Y F, Wang M H 2022 Compos. Part B 242 110033 Google Scholar
[33]	Zhang E R, Yao Y P, Gao T Y, Kang D D, Wu J H, Dai J Y 2019 J. Chem. Phys. 151 064116 Google Scholar
[34]	Yang Y, Cao J, Wei N, Meng D H, Wang L N, Ren G H, Yan R X, Zhang N 2019 Molecules 24 1103 Google Scholar
[35]	Ghaderi H, Ghasemi H, Rouhi S, Mahdavi E 2021 Phys. E Low Dimens. Syst. Nanostruct. 134 114830 Google Scholar
[36]	Ding Z W, Pei Q X, Jiang J W, Zhang Y W 2015 J. Phys. Chem. C 119 16358 Google Scholar
[37]	Ahmadi M, Rouhi S, Ansari R 2021 J Mater. Design Appl. 235 2762 Google Scholar
[38]	Sun Y Y, Zhou L Y, Han Yu, Cui Liu, Chen L 2020 Int. J. Heat. Mass. Tran. 120 120517 Google Scholar
[39]	Dong K, Zhang J J, Jin L M, Gu B H, Sun B Z 2016 Compos. Struct. 143 9 Google Scholar
[40]	Qian L J, Pang X M, Zhou J Q, Yang J X, Lin S S, Hui D 2017 Compos. Part B 116 291 Google Scholar
[41]	Goodarzi B V, Bahramian A R 2022 J. Therm. Anal. Calorim. 147 6227 Google Scholar
[42]	Wu Y J, Fang L, Xu Y B 2019 NPJ Comput. Mater. 5 1 Google Scholar
[43]	Meshalkin Y, Shakirov A, Popov E, Koroteev D, Gurbatova I 2020 Geophys. J. Int. 222 978 Google Scholar
[44]	Sargam Y, Wang K J, Cho I H 2021 Build. Eng. 34 101956 Google Scholar
[45]	Li K Q, Liu Y, Kang Q 2022 Int. Commun. Heat Mass Transfer 136 106139 Google Scholar
[46]	Jiang Y L, Shi X J, Feng Y Z, Li S, Zhou X P, Xie X L 2018 Compos. Part A 107 657 Google Scholar
[47]	Li S S, Liu X, Fang C Q, Liu N L, Liu D H 2018 RSC Adv. 8 20505 Google Scholar
[48]	Goto T, Ito T, Mayumi K, Maeda R, Shimizu Y, Hatakeyama K, Kohzolto, Hakuta Y, Terashima 2020 Compos. Sci. Technol. 190 108009 Google Scholar
[49]	Lule Z, Kim J 2019 Polymer 11 148 Google Scholar
[50]	Hu D C, Liu H Q, Guo Y K, Yang M Z, Ma W S 2022 Compos. Part A 158 106970 Google Scholar
[51]	Shi Q, Zhu A P 2020 Prog. Org. Coat. 140 105480 Google Scholar
[52]	Ding D L, Wang H T, Wu Z Q, Chen Y H, Zhang Q Y 2019 Macromol. Rapid Commun. 40 1800805 Google Scholar
[53]	卢虹, 师雯, 周聪, 张梓楠, 游峰, 刘仿军 2021 胶体与聚合物 39 163 Google Scholar Lu H, Shi W, Zhou C, Zhang Z N, You F, Liu F J 2021 Coll. Poly. 39 163 Google Scholar
[54]	Zhang X D, Dong J W, Pan D, Yang G, Su F M, Ji Y X, Liu C T, Shen C Y 2021 Adv. Compos. Hybrid. Ma. 4 1102 Google Scholar
[55]	Zhou X N, Xu S S, Wang Z Y, Hao L C, Shi Z Q, Zhao J P, Zhang Q G, Ishizaki K, Wang Bo, Yang J F 2022 Adv. Sci. 9 2103592 Google Scholar
[56]	Lin Y, Kang Q, Wei H, Bao H, Jiang P K, Mai Y W, Huang X Y 2021 Nanomicro. Lett. 13 1 Google Scholar
[57]	Dong L, Xi Q, Chen D S, Guo J, Nakayama T, Li Y Y, Liang Z Q, Zhou J, Xu X F, Li B W 2018 Nat. Sci. Rev. 5 500 Google Scholar
[58]	Morikawa J, Hashimoto T 2009 J. Appl. Phys. 105 113506 Google Scholar
[59]	Xiao T C, Fan X, Fan D S, Li Q 2017 Polym. Bull. 74 4561 Google Scholar
[60]	Lei H Y, Zhang M Y, Niu H Q, Qi S L, Tian G F, Wu D Z 2018 Polymer 149 96 Google Scholar
[61]	Guo Z, Lee D, Liu Y, Sun F Y, Sliwinski A, Gao H F, Burns P, Luo T F 2014 Phys. Chem. Chem. Phys. 16 7764 Google Scholar
[62]	Ma H, Tian Z T 2019 J. Mater. Res. 34 126 Google Scholar
[63]	Shen S, Henry A, Tong J, Zheng R T, Chen G 2010 Nat. Nanotechnol. 5 251 Google Scholar
[64]	Ruan K P, Guo, Y Q, Gu J W 2021 Macromolecules 54 4934 Google Scholar
[65]	Shoji Y, Ishige R, Higashihara T, Morikawa J, Hashimoto T, Takahara A, Watanabet J, Ueda M 2013 Macromolecules 46 747 Google Scholar
[66]	Shoji Y, Ishige R, Higashihara T, Kawauchi S, Watanabe J, Ueda M 2010 Macromolecules 43 8950 Google Scholar
[67]	Schab-Balcerzak E, Iwan A, Grucela-Zajac M, Krompiec M, Podgorna M, Domanski, M, Siwy M Janeczek H 2011 Synth. Met. 161 1660 Google Scholar
[68]	龚莹, 周文英, 徐丽, 彭建东, 赵伟, 闫智伟 2017 中国塑料 31 1 Google Scholar Gong Y, Zhou W Y, Xu L, Peng J D, Zhao W, Yan Z W 2017 China Plastics 31 1 Google Scholar
[69]	Rivera Nicholls A, Pellisier M, Perez Y, Stock J A, Kull K, Julien T, Eubank J, Harmon J P 2019 Polym. Eng. Sci. 59 1948 Google Scholar
[70]	Kim G H, Lee D, Shanker A, Shao L, Kwon M S, Gidley D, Kim J, Pipe K P 2015 Nat. Mater. 14 295 Google Scholar
[71]	Gu J W, Yang X T, Lü Z Y, Li N, Liang C B, Zhang Q Y 2016 Int. J. Heat Mass. Transf. 92 15 Google Scholar
[72]	Hussain A R J, Alahyari A A, Eastman S A, Thibaud-Erkey C, Johnston S, Sobkowicz M J 2017 Appl. Therm. Eng. 113 1118 Google Scholar
[73]	Gong J R, Liu Z D, Yu J H, Dai D, Dai W, Du S Y, Li C Y, Jiang N, Zhan Z L, Lin C T 2016 Compos. Part A 87 290 Google Scholar
[74]	Wu X, Li H L, Cheng K, Qiu H X, Yang J H 2019 Nanoscale 11 8219 Google Scholar
[75]	Ma L, Wang Y X, Wang Y Y, Wang C G, Gao X P 2020 Ceram. Int. 46 3332 Google Scholar
[76]	Weng M M, Jian L F, Feng X, Luo X L, Hu J Q, Zhang J S, Liu Y D, Min Y G 2021 Ceram. Int. 47 24519 Google Scholar
[77]	Wang Y, Wang H T, Liu F, Wu X L, Xu J L, Cui H X, Wu Y J, Xue R, Tian C, Zheng B J, Yao W 2020 Compos. Part A 138 106075 Google Scholar
[78]	Guo Y Q, Ruan K P, Yang X T, Ma T B, Kong J, Wu N N, Zhang J X, Gu J W, Guo Z H 2019 J. Mater. Chem. C 7 7035 Google Scholar
[79]	Si Y C, Samulski E T 2008 Chem. Mater. 20 6792 Google Scholar
[80]	Guo Y Q, Yang X T, Ruan K P, Kong J, Dong M Y, Zhang J X, Gu J W, Guo Z H 2019 ACS Appl. Mater. Interfaces 11 25465 Google Scholar
[81]	An L L, Yang Z H, Zeng X L, Hu W B, Yu Y L, Zhang J Y, Wang Q H 2022 Chem. Eng. J. 431 133740 Google Scholar
[82]	Gu J W, Du J J, Dang J, Geng W C, Hu S H, Zhang Q Y 2014 RSC Adv. 4 22101 Google Scholar
[83]	Liu L Z, Cao C H, Ma X Y, Zhang X R, Lü T 2020 J. Macromol. Sci. A 57 398 Google Scholar
[84]	Huang C L, Qian X, Yang R G 2018 Mat. Sci. Eng. R 132 1 Google Scholar
[85]	He X H, Wang Y C 2020 Ind. Eng. Chem. Res. 59 1925 Google Scholar
[86]	Wang Y Y, Zhang X, Ding X, Li Y, Zhang P, Shu M T, Zhang Q, Gong Y, Zheng K, Wu B, Tian X Y 2021 Compos. Sci. Technol. 205 108693 Google Scholar
[87]	纪超 2020 硕士学位论文(深圳: 深圳大学) Ji C 2020 M. S. Thesis (Shenzhen: Shenzhen University) (in Chinese)
[88]	Leung S N, Khan M O, Chan E, Naguib H E, Dawson F, Adinkrah V, LakatosH L 2013 J Appl. Polym. Sci. 127 3293 Google Scholar
[89]	Liu D X, Ma C G, Chi H T, Li S H, Zhang P, Dai P B 2020 RSC Adv. 10 42584 Google Scholar
[90]	Che J J, Wu K, Lin Y J, Wang K, Fu Q 2017 Compos. Part A 99 32 Google Scholar
[91]	Wu K, Xue Y, Yang W X, Chai S G, Chen F, Fu Q 2016 Compos. Sci. Technol. 130 28 Google Scholar
[92]	Wei Y, Shi Y P, Jiang Z Y, Zhang X F, Chen H H, Zhang Y H, Zhang J W, Gong C H 2019 J. Alloys Compd. 810 151950 Google Scholar
[93]	Chen C, Li X J, Wen Y F, Liu J W, Li X W, Zeng H X, Xue Z G, Zhou X P, Xie X L 2019 Compos. Part A 125 105517 Google Scholar
[94]	马馨雨 2019 硕士学位论文 (哈尔滨: 哈尔滨理工大学) Ma X Y 2019 M. S. Thesis (Harbin: Harbin University of Science and Technology) (in Chinese)
[95]	Wang H, Xing W K, Chen S, Song C Y, Dickey M D, Deng T 2021 Adv. Mater. 33 2103104 Google Scholar
[96]	Feng C P, Wei F, Sun K Y, Wang Y, Lan H B, Shang H J, Ding F Z, Bai L, Yang J, Yang W 2022 Nanomicro Lett. 14 127 Google Scholar
[97]	Yang N, Xu C, Hou J, Yao Y M, Zhang Q X, Grami M E, He L Q, Wang N Y, Qu X W 2016 RSC Adv. 6 18279 Google Scholar
[98]	杨曦, 姚亚超, 张伯涵, 苏创, 于晓燕 2016 胶体与聚合物 34 19 Google Scholar Yang X, Yao Y C, Zhang B H, Su C, Yu X Y 2016 Coll. Poly. 34 19 Google Scholar
[99]	Xie Z L, Wu K, Liu D Y, Zhang Q, Fu Q 2021 Compo. Sci. Technol. 208 108756 Google Scholar
[100]	Li H Y, Li R Y, Liu H L, Wang D M, Zhang P Y, Liu T, Yang A W 2019 Emerg. Mater. Res. 8 55 Google Scholar
[101]	Cao L, Wang J J, Dong J, Zhao X, Li H B, Zhang Q H 2020 Compos. Part B 188 107882 Google Scholar
[102]	Xu L B, Chen G F, Wang W, Li L, Fang X Z 2016 Compos. Part A 84 472 Google Scholar
[103]	Ding D L, Shang Z H, Zhang X, Lei X F, Liu Z G, Zhang Q Y, Chen Y H 2020 Ceram. Int. 46 28363 Google Scholar
[104]	王雨婷, 吴子剑, 王正芳, 王雪霏, 郭宁, 张笑瑞, 马英一, 陈昊, 翁凌 2021 绝缘材料 54 120 Google Scholar Wang Y T, Wu Z J, Wang Z F, Wang X F, Guo N, Zhang X R, Ma Y Y, Chen H, Weng L 2021 Insul. Mater. 54 120 Google Scholar
[105]	Duan G Y, Cao Y T, Quan J Y, Hu Z M, Wang Y, Yu J R, Zhu J 2020 J. Mater. Sci. 55 8170 Google Scholar
[106]	Dong J, Cao L, Li Y, Wu Z Q, Teng C Q 2020 Compos. Sci. Technol. 196 108242 Google Scholar
[107]	曹金梅, 田付强, 雷清泉 2022 科学通报 67 640 Cao J M, Tian F Q, Lei Q Q 2022 Sci. Bull. 67 640
[108]	Jiang T, Carbone E J, Lo K W H, Laurencin C T 2015 Prog. Polym. Sci. 46 1 Google Scholar
[109]	Li Z, Yin Q F, Hu W W, Zhang J W, Guo J H, Chen J P, Sun T H, Du C Q, Shu J, Yu L G, Zhang J W 2019 J. Mater. Sci. 54 9025 Google Scholar
[110]	Guo Y Q, Xu G J, Yang X T, Ruan K P, Ma T B, Zhang Q Y, Gu J W, Wu Y L, Liu Hu, Guo Z H 2018 J. Mater. Chem. C 6 3004 Google Scholar
[111]	Guo Y Q, Qiu H, Ruan K P, Zhang Y L, Gu J W 2022 Nanomicro Lett. 14 26 Google Scholar
[112]	Wei S Y, Yu Q X, Fan Z G, Liu S W, Chi Z G, Chen X D, Zhang Y, Xu J R 2018 RSC Adv. 8 22169 Google Scholar
[113]	Liu D X, Chi H T, Ma C G, Song M Y, Zhang P, Dai P B 2022 Compos. Sci. Technol. 220 109292 Google Scholar
[114]	Chung S H, Kim J T, Kim H, Kim D H, Jeong S W 2022 Mater. Today Commun. 30 103026 Google Scholar

施引文献

图 1 PI薄膜材料的应用^[3-7]

Fig. 1. Application of PI film materials^[3-7].

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图 2 粒子碰撞在材料中的热传导^[12]

Fig. 2. Thermal conduction in material by collision of particles^[12].

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图 3 聚合物的导热机理^[14]

Fig. 3. Thermal conductivity mechanism of polymers^[14].

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图 4 两步法合成PI的路线

Fig. 4. PI two-step synthesis route.

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图 5 导热网络形成示意图^[19]

Fig. 5. Schematic diagram of the formation of thermal conduction network^[19].

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图 6 导热系数的计算模型^[24]

Fig. 6. Calculation model of thermal conductivity^[24].

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图 7 PI基复合材料内部的传热模拟^[27]

Fig. 7. Heat transfer simulation inside the PI-based composites^[27].

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图 8 PI-1, PI-2, PI-3, PI-4的化学结构^[59]

Fig. 8. Chemical structures of PI-1, PI-2, PI-3 and PI-4^[59].

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图 9 PI纤维的分子堆积模型^[60]

Fig. 9. The molecular packing model of the PI fibers^[60].

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图 10 具有三明治结构的G-FPC^[77]

Fig. 10. Schematic of G-FPC with sandwich structure^[77].

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图 11 不同质量含量BN的PI复合薄膜的导热系数(a)和导热系数的增强(b)^[85]

Fig. 11. Thermal conductivity (a) and thermal conductivity enhancement (b) of PI composite films with different weight contents of BN^[85].

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图 12 不同混合填料形成的单网络示意图^[84]　(a) 0D+1D填料; (b) 0D+2D填料; (c) 1D+2D填料

Fig. 12. Schematic diagrams of single network formed with different hybrid fillers^[84]: (a) 0D+1D fillers; (b) 0D+2D fillers; (c) 1D +2D fillers.

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图 13 Al₂O₃@BN和Al₂O₃@BN&BN/PI复合薄膜的制备工艺示意图^[89]

Fig. 13. Schematic illustration of Al₂O₃@BN preparation and fabrication process of the Al₂O₃@BN&BN/PI composite film^[89].

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图 14 PI复合膜的导热网络示意图^[54]　(a) PI/BNNS单导热网络; (b) PI/BNNS/CNT@αPVA双导热网络

Fig. 14. Schematic diagram of the thermal conductivitynetwork of PI composite films^[54]: (a) PI/BNNS single thermally conductive network; (b) PI/BNNS/CNT@αPVA double thermally conductive networks.

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图 15 降低界面热阻的有效策略^[96]

Fig. 15. Effective strategies for reducing interfacial thermal resistance^[96].

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图 16 PI复合材料的平面热导率(a)和跨平面热导率(b)^[105]

Fig. 16. Thermal conductivity in-plane (a) and through- plane (b) of PI composites^[105].

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图 17 复合膜的运动磁场感应和热传导机理图^[113]

Fig. 17. Schematic diagram of the moving magnetic field induction and heat conduction mechanism^[113].

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表 1 常见聚合物的热导率

Table 1. Thermal conductivity of the common polymers.

材料名称	热导率/(W·m^–1·K^–1)
环氧树脂 (EP)	0.20—0.88
聚氨酯 (PU)	0.25
聚偏氯乙烯 (PVDF)	0.19
聚二甲基硅氧烷 (PDMS)	0.19
聚苯乙烯 (PS)	0.18
低密度聚乙烯 (LDPE)	0.32—0.40
高密度聚乙烯 (HDPE)	0.38—0.51
聚丙烯 (PP)	0.17—0.22
聚醚醚酮 (PEEK)	0.25
聚氯乙烯 (PVC)	0.14—0.17
聚酰亚胺 (PI)	0.10—0.35
聚乙烯醇 (PVA)	0.20
聚四氟乙烯(PTFE)	0.25
聚甲醛 (POM)	0.40

下载: 导出CSV

[1]	Song N, Cao D, Luo X, Wang Q, Ding P, Shi L 2020 Compos. Part A 135 105912 Google Scholar
[2]	刘裕芮, 许艳菲 2022 物理学报 71 023601 Google Scholar Liu Y R, Xu Y F 2022 Acta Phys. Sin. 71 023601 Google Scholar
[3]	Lian R, Lei X, Chen Y, Zhang Q 2019 J. Appl. Polym. Sci. 136 47771 Google Scholar
[4]	Govindaraj B, Sarojadevi M 2018 Polym. Adv. Technol. 29 1718 Google Scholar
[5]	刘金刚, 张秀敏, 田付强, 杨士勇 2017 电工技术学报 32 14 Google Scholar Liu J G, Zhang X M, Tian F Q, Yang S Y 2017 Trans. CES. 32 14 Google Scholar
[6]	Gu J W, Lü Z Y, Wu Y L, Guo Y Q, Tian L D, Qiu H, Li W Z, Zhang Q Y 2017 Compos. Part A 94 209 Google Scholar
[7]	杨娜 2016 硕士学位论文 (天津: 河北工业大学) Yang N 2016 M. S. Thesis (Tianjin: Hebei University of Technology) (in Chinese)
[8]	潘东楷, 宗志成, 杨诺 2022 物理学报 71 086302 Google Scholar Pan D K, Zong Z C, Yang N 2022 Acta Phys. Sin. 71 086302 Google Scholar
[9]	高梦岩, 王畅鸥, 贾妍, 翟磊, 莫松, 何民辉, 范琳 2021 绝缘材料 54 1 Gao M Y, Wang C O, Jia Y, Zhai L, Mo S, He M H, Fan L 2021 Insul. Mater. 54 1
[10]	Zhao L H, Wang L, Jin Y F, Ren J W, Wang Z, Jia L C 2022 Compos. Part B 229 109454 Google Scholar
[11]	Zhang L, Deng H, Fu Q 2018 Compos. Commun. 8 74 Google Scholar
[12]	王春博 2020 博士学位论文(吉林: 吉林大学) Wang C B 2020 Ph. D. Dissertation (Jilin: Jilin University) (in Chinese)
[13]	王艳艳 2021 博士学位论文(安徽: 中国科学技术大学) WangY Y 2021 Ph. D. Dissertation (Anhui: University of Science and Technology of China) (in Chinese)
[14]	田付强, 熊雯雯, 夏宇, 杨春 2020 绝缘材料 53 1 Google Scholar Tian F Q, Xiong W W, Xia Y, Yang C 2020 Insul. Mater. 53 1 Google Scholar
[15]	曲可新 2022 硕士学位论文 (哈尔滨: 哈尔滨理工大学) Qu K X 2022 M. S. Thesis (Harbin: Harbin University of Science and Technology) (in Chinese)
[16]	Liu J, Yang R G 2012 Phys. Rev. B 86 104307 Google Scholar
[17]	周文英, 王蕴, 曹国政, 曹丹, 李婷, 张祥林 2021 复合材料学报 38 2038 Google Scholar Zhou W Y, Wang Y, Cao G Z, Cao D, Li T, Zhang X L 2021 Acta Mate. Compos. Sin. 38 2038 Google Scholar
[18]	Guo Y Q, Ruan K P, Shi X T, Yang X T, Gu J W 2020 Compos. Sci. Technol. 193 108134 Google Scholar
[19]	何亭融, 曲绍宁, 尹训茜 2022 绝缘材料 53 12 Google Scholar He T R, Qu S N, Yin X X 2022 Insul. Mater. 53 12 Google Scholar
[20]	Chen H Y, Ginzburg V V, Yang J, Yang Y F, Liu W, Huang Y, Du L B, Chen B 2016 Prog. Polym. Sci. 59 41 Google Scholar
[21]	许星星 2018 硕士学位论文(重庆: 重庆邮电大学) Xu X X 2018 M. S. Thesis (Chongqing: Chongqing University of Posts and Telecommunications) (in Chinese)
[22]	蒋涛, 邬涵, 张群朝, 郝同辉 2019 湖北大学学报(自然科学版) 41 526 Google Scholar Jiang T, Wu H, Zhang Q C, Hao T H 2019 Hubei Univ. (Nat. Sci. Ed. ) 41 526 Google Scholar
[23]	兰生, 李焜, 高新昀 2017 物理学报 66 136801 Google Scholar Lan S, Li K, Gao X Y 2017 Acta Phys. Sin. 66 136801 Google Scholar
[24]	徐京城, 戴思畅, 李昊亮, 杨俊和 2018 新型炭材料 33 213 Google Scholar Xu J C, Dai S C, Li H L, Yang J H 2018 New Carb. Mater. 33 213 Google Scholar
[25]	Wang X S, Zhao T, Wang Y H, Zhang L, Zou L, Zhang Y T 2022 Comput. Mater. Sci. 210 111051 Google Scholar
[26]	Zhu M X, Song H G, Yu Q C, Chen J M, Zhang H Y 2020 Int. J. Heat. Mass. Tran. 162 120381 Google Scholar
[27]	Guo Y Q, Wang S S, Ruan K P, Zhang H T, Gu J W 2021 Npj Flex. Elec. 5 16 Google Scholar
[28]	Ding D L, Zou M H, Wang X, Qin G Z, Zhang S Y, Chan S Y, Meng Q Y, Liu Z G, Zhang Q Y, Chen Y H 2022 Chem. Eng. J. 437 135438 Google Scholar
[29]	Wu S, Kondo Y, Kakimoto M, et al. 2019 NPJ Comput. Mater. 5 66 Google Scholar
[30]	张萌萌, 贾广跃, 熊丽萍, 何忠义, 晏金灿, 纪红兵 2020 精细化工 37 1081 Google Scholar Zhang M M, Jia G Y, Xiong L P, He Z Y, Yan J C, Ji H B 2020 Fine Chem. 37 1081 Google Scholar
[31]	Zhu C Y, Yang W X, Xu H B, Ding B, Gong L, Li Z Y 2021 Int. J. Therm. Sci. 168 107088 Google Scholar
[32]	Dong M J, Hou G Y, Zhang J C, Liu Li, Liang G Y, Hao X M, Guo Y F, Wang M H 2022 Compos. Part B 242 110033 Google Scholar
[33]	Zhang E R, Yao Y P, Gao T Y, Kang D D, Wu J H, Dai J Y 2019 J. Chem. Phys. 151 064116 Google Scholar
[34]	Yang Y, Cao J, Wei N, Meng D H, Wang L N, Ren G H, Yan R X, Zhang N 2019 Molecules 24 1103 Google Scholar
[35]	Ghaderi H, Ghasemi H, Rouhi S, Mahdavi E 2021 Phys. E Low Dimens. Syst. Nanostruct. 134 114830 Google Scholar
[36]	Ding Z W, Pei Q X, Jiang J W, Zhang Y W 2015 J. Phys. Chem. C 119 16358 Google Scholar
[37]	Ahmadi M, Rouhi S, Ansari R 2021 J Mater. Design Appl. 235 2762 Google Scholar
[38]	Sun Y Y, Zhou L Y, Han Yu, Cui Liu, Chen L 2020 Int. J. Heat. Mass. Tran. 120 120517 Google Scholar
[39]	Dong K, Zhang J J, Jin L M, Gu B H, Sun B Z 2016 Compos. Struct. 143 9 Google Scholar
[40]	Qian L J, Pang X M, Zhou J Q, Yang J X, Lin S S, Hui D 2017 Compos. Part B 116 291 Google Scholar
[41]	Goodarzi B V, Bahramian A R 2022 J. Therm. Anal. Calorim. 147 6227 Google Scholar
[42]	Wu Y J, Fang L, Xu Y B 2019 NPJ Comput. Mater. 5 1 Google Scholar
[43]	Meshalkin Y, Shakirov A, Popov E, Koroteev D, Gurbatova I 2020 Geophys. J. Int. 222 978 Google Scholar
[44]	Sargam Y, Wang K J, Cho I H 2021 Build. Eng. 34 101956 Google Scholar
[45]	Li K Q, Liu Y, Kang Q 2022 Int. Commun. Heat Mass Transfer 136 106139 Google Scholar
[46]	Jiang Y L, Shi X J, Feng Y Z, Li S, Zhou X P, Xie X L 2018 Compos. Part A 107 657 Google Scholar
[47]	Li S S, Liu X, Fang C Q, Liu N L, Liu D H 2018 RSC Adv. 8 20505 Google Scholar
[48]	Goto T, Ito T, Mayumi K, Maeda R, Shimizu Y, Hatakeyama K, Kohzolto, Hakuta Y, Terashima 2020 Compos. Sci. Technol. 190 108009 Google Scholar
[49]	Lule Z, Kim J 2019 Polymer 11 148 Google Scholar
[50]	Hu D C, Liu H Q, Guo Y K, Yang M Z, Ma W S 2022 Compos. Part A 158 106970 Google Scholar
[51]	Shi Q, Zhu A P 2020 Prog. Org. Coat. 140 105480 Google Scholar
[52]	Ding D L, Wang H T, Wu Z Q, Chen Y H, Zhang Q Y 2019 Macromol. Rapid Commun. 40 1800805 Google Scholar
[53]	卢虹, 师雯, 周聪, 张梓楠, 游峰, 刘仿军 2021 胶体与聚合物 39 163 Google Scholar Lu H, Shi W, Zhou C, Zhang Z N, You F, Liu F J 2021 Coll. Poly. 39 163 Google Scholar
[54]	Zhang X D, Dong J W, Pan D, Yang G, Su F M, Ji Y X, Liu C T, Shen C Y 2021 Adv. Compos. Hybrid. Ma. 4 1102 Google Scholar
[55]	Zhou X N, Xu S S, Wang Z Y, Hao L C, Shi Z Q, Zhao J P, Zhang Q G, Ishizaki K, Wang Bo, Yang J F 2022 Adv. Sci. 9 2103592 Google Scholar
[56]	Lin Y, Kang Q, Wei H, Bao H, Jiang P K, Mai Y W, Huang X Y 2021 Nanomicro. Lett. 13 1 Google Scholar
[57]	Dong L, Xi Q, Chen D S, Guo J, Nakayama T, Li Y Y, Liang Z Q, Zhou J, Xu X F, Li B W 2018 Nat. Sci. Rev. 5 500 Google Scholar
[58]	Morikawa J, Hashimoto T 2009 J. Appl. Phys. 105 113506 Google Scholar
[59]	Xiao T C, Fan X, Fan D S, Li Q 2017 Polym. Bull. 74 4561 Google Scholar
[60]	Lei H Y, Zhang M Y, Niu H Q, Qi S L, Tian G F, Wu D Z 2018 Polymer 149 96 Google Scholar
[61]	Guo Z, Lee D, Liu Y, Sun F Y, Sliwinski A, Gao H F, Burns P, Luo T F 2014 Phys. Chem. Chem. Phys. 16 7764 Google Scholar
[62]	Ma H, Tian Z T 2019 J. Mater. Res. 34 126 Google Scholar
[63]	Shen S, Henry A, Tong J, Zheng R T, Chen G 2010 Nat. Nanotechnol. 5 251 Google Scholar
[64]	Ruan K P, Guo, Y Q, Gu J W 2021 Macromolecules 54 4934 Google Scholar
[65]	Shoji Y, Ishige R, Higashihara T, Morikawa J, Hashimoto T, Takahara A, Watanabet J, Ueda M 2013 Macromolecules 46 747 Google Scholar
[66]	Shoji Y, Ishige R, Higashihara T, Kawauchi S, Watanabe J, Ueda M 2010 Macromolecules 43 8950 Google Scholar
[67]	Schab-Balcerzak E, Iwan A, Grucela-Zajac M, Krompiec M, Podgorna M, Domanski, M, Siwy M Janeczek H 2011 Synth. Met. 161 1660 Google Scholar
[68]	龚莹, 周文英, 徐丽, 彭建东, 赵伟, 闫智伟 2017 中国塑料 31 1 Google Scholar Gong Y, Zhou W Y, Xu L, Peng J D, Zhao W, Yan Z W 2017 China Plastics 31 1 Google Scholar
[69]	Rivera Nicholls A, Pellisier M, Perez Y, Stock J A, Kull K, Julien T, Eubank J, Harmon J P 2019 Polym. Eng. Sci. 59 1948 Google Scholar
[70]	Kim G H, Lee D, Shanker A, Shao L, Kwon M S, Gidley D, Kim J, Pipe K P 2015 Nat. Mater. 14 295 Google Scholar
[71]	Gu J W, Yang X T, Lü Z Y, Li N, Liang C B, Zhang Q Y 2016 Int. J. Heat Mass. Transf. 92 15 Google Scholar
[72]	Hussain A R J, Alahyari A A, Eastman S A, Thibaud-Erkey C, Johnston S, Sobkowicz M J 2017 Appl. Therm. Eng. 113 1118 Google Scholar
[73]	Gong J R, Liu Z D, Yu J H, Dai D, Dai W, Du S Y, Li C Y, Jiang N, Zhan Z L, Lin C T 2016 Compos. Part A 87 290 Google Scholar
[74]	Wu X, Li H L, Cheng K, Qiu H X, Yang J H 2019 Nanoscale 11 8219 Google Scholar
[75]	Ma L, Wang Y X, Wang Y Y, Wang C G, Gao X P 2020 Ceram. Int. 46 3332 Google Scholar
[76]	Weng M M, Jian L F, Feng X, Luo X L, Hu J Q, Zhang J S, Liu Y D, Min Y G 2021 Ceram. Int. 47 24519 Google Scholar
[77]	Wang Y, Wang H T, Liu F, Wu X L, Xu J L, Cui H X, Wu Y J, Xue R, Tian C, Zheng B J, Yao W 2020 Compos. Part A 138 106075 Google Scholar
[78]	Guo Y Q, Ruan K P, Yang X T, Ma T B, Kong J, Wu N N, Zhang J X, Gu J W, Guo Z H 2019 J. Mater. Chem. C 7 7035 Google Scholar
[79]	Si Y C, Samulski E T 2008 Chem. Mater. 20 6792 Google Scholar
[80]	Guo Y Q, Yang X T, Ruan K P, Kong J, Dong M Y, Zhang J X, Gu J W, Guo Z H 2019 ACS Appl. Mater. Interfaces 11 25465 Google Scholar
[81]	An L L, Yang Z H, Zeng X L, Hu W B, Yu Y L, Zhang J Y, Wang Q H 2022 Chem. Eng. J. 431 133740 Google Scholar
[82]	Gu J W, Du J J, Dang J, Geng W C, Hu S H, Zhang Q Y 2014 RSC Adv. 4 22101 Google Scholar
[83]	Liu L Z, Cao C H, Ma X Y, Zhang X R, Lü T 2020 J. Macromol. Sci. A 57 398 Google Scholar
[84]	Huang C L, Qian X, Yang R G 2018 Mat. Sci. Eng. R 132 1 Google Scholar
[85]	He X H, Wang Y C 2020 Ind. Eng. Chem. Res. 59 1925 Google Scholar
[86]	Wang Y Y, Zhang X, Ding X, Li Y, Zhang P, Shu M T, Zhang Q, Gong Y, Zheng K, Wu B, Tian X Y 2021 Compos. Sci. Technol. 205 108693 Google Scholar
[87]	纪超 2020 硕士学位论文(深圳: 深圳大学) Ji C 2020 M. S. Thesis (Shenzhen: Shenzhen University) (in Chinese)
[88]	Leung S N, Khan M O, Chan E, Naguib H E, Dawson F, Adinkrah V, LakatosH L 2013 J Appl. Polym. Sci. 127 3293 Google Scholar
[89]	Liu D X, Ma C G, Chi H T, Li S H, Zhang P, Dai P B 2020 RSC Adv. 10 42584 Google Scholar
[90]	Che J J, Wu K, Lin Y J, Wang K, Fu Q 2017 Compos. Part A 99 32 Google Scholar
[91]	Wu K, Xue Y, Yang W X, Chai S G, Chen F, Fu Q 2016 Compos. Sci. Technol. 130 28 Google Scholar
[92]	Wei Y, Shi Y P, Jiang Z Y, Zhang X F, Chen H H, Zhang Y H, Zhang J W, Gong C H 2019 J. Alloys Compd. 810 151950 Google Scholar
[93]	Chen C, Li X J, Wen Y F, Liu J W, Li X W, Zeng H X, Xue Z G, Zhou X P, Xie X L 2019 Compos. Part A 125 105517 Google Scholar
[94]	马馨雨 2019 硕士学位论文 (哈尔滨: 哈尔滨理工大学) Ma X Y 2019 M. S. Thesis (Harbin: Harbin University of Science and Technology) (in Chinese)
[95]	Wang H, Xing W K, Chen S, Song C Y, Dickey M D, Deng T 2021 Adv. Mater. 33 2103104 Google Scholar
[96]	Feng C P, Wei F, Sun K Y, Wang Y, Lan H B, Shang H J, Ding F Z, Bai L, Yang J, Yang W 2022 Nanomicro Lett. 14 127 Google Scholar
[97]	Yang N, Xu C, Hou J, Yao Y M, Zhang Q X, Grami M E, He L Q, Wang N Y, Qu X W 2016 RSC Adv. 6 18279 Google Scholar
[98]	杨曦, 姚亚超, 张伯涵, 苏创, 于晓燕 2016 胶体与聚合物 34 19 Google Scholar Yang X, Yao Y C, Zhang B H, Su C, Yu X Y 2016 Coll. Poly. 34 19 Google Scholar
[99]	Xie Z L, Wu K, Liu D Y, Zhang Q, Fu Q 2021 Compo. Sci. Technol. 208 108756 Google Scholar
[100]	Li H Y, Li R Y, Liu H L, Wang D M, Zhang P Y, Liu T, Yang A W 2019 Emerg. Mater. Res. 8 55 Google Scholar
[101]	Cao L, Wang J J, Dong J, Zhao X, Li H B, Zhang Q H 2020 Compos. Part B 188 107882 Google Scholar
[102]	Xu L B, Chen G F, Wang W, Li L, Fang X Z 2016 Compos. Part A 84 472 Google Scholar
[103]	Ding D L, Shang Z H, Zhang X, Lei X F, Liu Z G, Zhang Q Y, Chen Y H 2020 Ceram. Int. 46 28363 Google Scholar
[104]	王雨婷, 吴子剑, 王正芳, 王雪霏, 郭宁, 张笑瑞, 马英一, 陈昊, 翁凌 2021 绝缘材料 54 120 Google Scholar Wang Y T, Wu Z J, Wang Z F, Wang X F, Guo N, Zhang X R, Ma Y Y, Chen H, Weng L 2021 Insul. Mater. 54 120 Google Scholar
[105]	Duan G Y, Cao Y T, Quan J Y, Hu Z M, Wang Y, Yu J R, Zhu J 2020 J. Mater. Sci. 55 8170 Google Scholar
[106]	Dong J, Cao L, Li Y, Wu Z Q, Teng C Q 2020 Compos. Sci. Technol. 196 108242 Google Scholar
[107]	曹金梅, 田付强, 雷清泉 2022 科学通报 67 640 Cao J M, Tian F Q, Lei Q Q 2022 Sci. Bull. 67 640
[108]	Jiang T, Carbone E J, Lo K W H, Laurencin C T 2015 Prog. Polym. Sci. 46 1 Google Scholar
[109]	Li Z, Yin Q F, Hu W W, Zhang J W, Guo J H, Chen J P, Sun T H, Du C Q, Shu J, Yu L G, Zhang J W 2019 J. Mater. Sci. 54 9025 Google Scholar
[110]	Guo Y Q, Xu G J, Yang X T, Ruan K P, Ma T B, Zhang Q Y, Gu J W, Wu Y L, Liu Hu, Guo Z H 2018 J. Mater. Chem. C 6 3004 Google Scholar
[111]	Guo Y Q, Qiu H, Ruan K P, Zhang Y L, Gu J W 2022 Nanomicro Lett. 14 26 Google Scholar
[112]	Wei S Y, Yu Q X, Fan Z G, Liu S W, Chi Z G, Chen X D, Zhang Y, Xu J R 2018 RSC Adv. 8 22169 Google Scholar
[113]	Liu D X, Chi H T, Ma C G, Song M Y, Zhang P, Dai P B 2022 Compos. Sci. Technol. 220 109292 Google Scholar
[114]	Chung S H, Kim J T, Kim H, Kim D H, Jeong S W 2022 Mater. Today Commun. 30 103026 Google Scholar

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