Recent Advances in the Rational Design of Thermal Conductive Polymer Composites

被引:99
作者
He, Xuhua [1 ]
Wang, Yuechuan [1 ]
机构
[1] Sichuan Univ, Coll Polymer Sci & Engn, State Key Lab Polymer Mat Engn, Chengdu 610065, Peoples R China
来源
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH | 2021年 / 60卷 / 03期
关键词
FUNCTIONALIZED BORON-NITRIDE; INTERFACE MATERIALS; POLYIMIDE COMPOSITES; ELECTRIC-FIELD; GRAPHENE; ENHANCEMENT; TRANSPORT; FILMS; MANAGEMENT; CELLULOSE;
D O I
10.1021/acs.iecr.0c05509
中图分类号
TQ [化学工业];
学科分类号
0817 ;
摘要
Most polymers possess low thermal conductivity and are therefore limited in thermal management applications. A key solution is to develop highly thermally conductive polymer composites by incorporating fillers into the polymer matrix, which has attracted intensive research efforts. Here we review recent advances in the rational design of thermal conductive polymer composites from both theoretical and experimental perspectives. First, the basic theories of thermal conduction in polymer composites are discussed. Second, special attention is given to the state-of-the-art design strategies that take into account the polymer-additive interface and the preconstruction of composite microstructure. Finally, the existing challenges and opportunities for future research in this field are highlighted.
引用
收藏
页码:1137 / 1154
页数:18
相关论文
共 141 条
[1]   In situ formation of a cellular graphene framework in thermoplastic composites leading to superior thermal conductivity [J].
Alam, Fakhr E. ;
Dai, Wen ;
Yang, Minghui ;
Du, Shiyu ;
Li, Xinming ;
Yu, Jinhong ;
Jiang, Nan ;
Lin, Cheng-Te .
JOURNAL OF MATERIALS CHEMISTRY A, 2017, 5 (13) :6164-6169
[2]   Flexible thermal interfacial materials with covalent bond connections for improving high thermal conductivity [J].
An, Dong ;
Cheng, Shuaishuai ;
Xi, Shuang ;
Zhang, Zhiyi ;
Duan, Xiaoyuan ;
Ren, Yanjuan ;
Li, Jiaxiong ;
Sun, Zhijian ;
Liu, Yaqing ;
Wong, Ching-Ping .
CHEMICAL ENGINEERING JOURNAL, 2020, 383
[3]   Electric field as a tuning key to process carbon nanotube suspensions with controlled conductivity [J].
Badard, M. ;
Combessis, A. ;
Allais, A. ;
Flandin, L. .
POLYMER, 2016, 82 :198-205
[4]  
Balandin AA, 2011, NAT MATER, V10, P569, DOI [10.1038/NMAT3064, 10.1038/nmat3064]
[5]   Thermal Properties of the Binary-Filler Hybrid Composites with Graphene and Copper Nanoparticles [J].
Barani, Zahra ;
Mohammadzadeh, Amirmahdi ;
Geremew, Adane ;
Huang, Chun-Yu ;
Coleman, Devin ;
Mangolini, Lorenzo ;
Kargar, Fariborz ;
Balandin, Alexander A. .
ADVANCED FUNCTIONAL MATERIALS, 2020, 30 (08)
[6]   Calculation of various physics constants in heterogenous substances I Dielectricity constants and conductivity of mixed bodies from isotropic substances [J].
Bruggeman, DAG .
ANNALEN DER PHYSIK, 1935, 24 (07) :636-664
[7]   Review of thermal conductivity in composites: Mechanisms, parameters and theory [J].
Burger, N. ;
Laachachi, A. ;
Ferriol, M. ;
Lutz, M. ;
Toniazzo, V. ;
Ruch, D. .
PROGRESS IN POLYMER SCIENCE, 2016, 61 :1-28
[8]   Thermal conductivity of polymer-based composites: Fundamentals and applications [J].
Chen, Hongyu ;
Ginzburg, Valeriy V. ;
Yang, Jian ;
Yang, Yunfeng ;
Liu, Wei ;
Huang, Yan ;
Du, Libo ;
Chen, Bin .
PROGRESS IN POLYMER SCIENCE, 2016, 59 :41-85
[9]   Millefeuille-Inspired Thermally Conductive Polymer Nanocomposites with Overlapping BN Nanosheets for Thermal Management Applications [J].
Chen, Jin ;
Wei, Han ;
Bao, Hua ;
Jiang, Pingkai ;
Huang, Xingyi .
ACS APPLIED MATERIALS & INTERFACES, 2019, 11 (34) :31402-31410
[10]   Highly Thermally Conductive Yet Electrically Insulating Polymer/Boron Nitride Nanosheets Nanocomposite Films for Improved Thermal Management Capability [J].
Chen, Jin ;
Huang, Xingyi ;
Sun, Bin ;
Jiang, Pingkai .
ACS NANO, 2019, 13 (01) :337-345
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