Study of carbon nanotube/epoxy composite films for high thermal conductivity and flexible modification

被引:0
|
作者
机构
[1] Wang, Miao
[2] Li, Qiang
[3] Xuan, Yi-Min
来源
Li, Q. (liqiang@mail.njust.edu.cn) | 1600年 / Science Press卷 / 34期
关键词
Carbon nanotubes - Yarn - Nanocomposite films - Thermal conductivity - Carbon films - Polymer films - Chemical vapor deposition;
D O I
暂无
中图分类号
学科分类号
摘要
Carbon nanotube arrays were fabricated via floating catalyst chemical vapor deposition(CVD), with diameter about 80 nm and height of 400~500 μm. Epoxy was designed to composite with carbon nanotube arrays for preparing CNTAs/epoxy composite films. Further, DBP as a toughen agent was added into epoxy polymer before compositing in order to make CNTAs/epoxy composite films infiltrated better, less space and more flexibility. When DBP weight percent was 10%, the thermal conductivity of CNTAs/epoxy composite films was 12.5 W/(m·K), and with DBP percent increased, the thermal conductivity and electric properties decreased because of its low thermal conductivity and density. 20% of DBP was a turning point that has the best ductility.
引用
收藏
相关论文
共 50 条
  • [41] Influence of carbon nanotube clustering on the electrical conductivity of polymer composite films
    Aguilar, J. O.
    Bautista-Quijano, J. R.
    Aviles, F.
    EXPRESS POLYMER LETTERS, 2010, 4 (05): : 292 - 299
  • [42] Study on metal decorated oxidized multiwalled carbon nanotube (MWCNT) - epoxy adhesive for thermal conductivity applications
    Amit K. Singh
    Bishnu P. Panda
    Smita Mohanty
    Sanjay K. Nayak
    Manoj K. Gupta
    Journal of Materials Science: Materials in Electronics, 2017, 28 : 8908 - 8920
  • [43] Study on metal decorated oxidized multiwalled carbon nanotube (MWCNT) - epoxy adhesive for thermal conductivity applications
    Singh, Amit K.
    Panda, Bishnu P.
    Mohanty, Smita
    Nayak, Sanjay K.
    Gupta, Manoj K.
    JOURNAL OF MATERIALS SCIENCE-MATERIALS IN ELECTRONICS, 2017, 28 (12) : 8908 - 8920
  • [44] Interface modification of carbon fiber reinforced epoxy composite by hydroxyl/carboxyl functionalized carbon nanotube
    De, Soubhik
    Fulmali, Abhinav Omprakash
    Shivangi, P. N.
    Choudhury, Saswat
    Prusty, Rajesh Kumar
    Ray, Bankim Chandra
    MATERIALS TODAY-PROCEEDINGS, 2020, 27 : 1473 - 1478
  • [45] The thermal properties of a carbon nanotube-enriched epoxy: Thermal conductivity, curing, and degradation kinetics
    Ventura, Isaac Aguilar
    Rahaman, Ariful
    Lubineau, Gilles
    JOURNAL OF APPLIED POLYMER SCIENCE, 2013, 130 (04) : 2722 - 2733
  • [46] Flexible Molybdenum Disulfide/Carbon Nanotube Composite Films for Thermoelectric Applications
    Li, Qinglin
    Li, Ping
    Li, Yanke
    Sidike, Saiyaer
    Xu, Yueling
    Wang, Yuchen
    Hu, Zhi
    Guo, Mingming
    Zhang, Hanqi
    Zhang, Yichuan
    ENERGY MATERIAL ADVANCES, 2024, 5
  • [47] Experimental determination and modeling of thermal conductivity tensor of carbon/epoxy composite
    Villiere, Maxime
    Lecointe, Damien
    Sobotka, Vincent
    Boyard, Nicolas
    Delaunay, Didier
    COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING, 2013, 46 : 60 - 68
  • [48] A Study on Accelerated Thermal Aging of High Modulus Carbon/Epoxy Composite Material
    Min, Kyung Ju
    Choi, Ji-Ung
    Lee, Ho-Sung
    2015 THE 4TH INTERNATIONAL CONFERENCE ON MATERIAL SCIENCE AND ENGINEERING TECHNOLOGY (ICMSET 2015), 2015, 30
  • [49] Flexible Carbon Nanotube Films for High Performance Strain Sensors
    Kanoun, Olfa
    Mueller, Christian
    Benchirouf, Abderahmane
    Sanli, Abdulkadir
    Trong Nghia Dinh
    Al-Hamry, Ammar
    Bu, Lei
    Gerlach, Carina
    Bouhamed, Ayda
    SENSORS, 2014, 14 (06): : 10042 - 10071
  • [50] Carbon-nanotube-polymer nanofibers with high thermal conductivity
    Datsyuk, Vitaliy
    Trotsenko, Svitlana
    Reich, Stephanie
    CARBON, 2013, 52 : 605 - 608
12345