Materials Reports 2019, Vol. 33 Issue (z1): 78-83 |
INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
|
|
|
|
|
Development Status of Carbon Nanotube Materials and Their Application Prospects in Spacecraft |
WANG Huifen1,2, LIU Gang1,2, CAO Kangli1,2, YANG Biqi1,2, XU Jun1,2, LAN Shaofei1,2, ZHANG Lixin1,2
|
1 Shanghai Institute of Satellite Equipment, Shanghai 200240 2 Shanghai Engineering Research Center of Space Environment Simulation and Verification, Shanghai 200240 |
|
|
Abstract Since its discovery more than 20 years ago, carbon nanotube has received a lot of attention around the world because of its excellent mecha-nical, thermal and electrical properties, showing great application prospects in high-tech fields and considered to be a booster for the next generation of aerospace vehicles. Following the introduction of performance characteristics and preparation methods, this paper reviews the development status and application prospects of carbon nanotube materials in aerospace field focusing on 3 aspects of light-weight structural enhancement, light-weight conductivity and efficient thermal management. The challenges of aerospace application are put forward
|
Published: 05 July 2019
|
|
About author:: Huifen Wang received her bachelor’s degree and master’s degree in materials science and engineering from Xi’an Jiaotong University in Sep. 2005—Jul. 2012. She was appointed to Shanghai Institute of Satellite Equipment upon graduation, and is currently a R & D engineer of the institute. She was selected for “ Shanghai Sailing Program” in 2017 . She has published nearly 20 journal or conference papers, applied 7 national invention patents and 5 of them were authorized. Her research interests focus on the application of nano material in spacecraft. She has been in charge of or participated in more than 10 projects, including the National Key R & D Program of China, the National Natural Science Funds and others. |
|
|
1 Meador M, Files B, Li J, et al. National NASA,2012. 2 Iijima S. Nature,1991,354,56. 3 Baughman R, ZakhidovA, de Heer W. Science,2002,297(787),787. 4 Wilder J W,Venema G, et al. Nature,1998,391(6662),59. 5 Bei Peng, Mark Locascio, et al. Nature Nanotechnology,2008,3,626. 6 Kwon Y K, Kim P. Physical Review Letters,2000,84,4613. 7 Cao J X, Yan X H, Xiao Y, et al. Physical Review B,2004,69,073407. 8 Iijima S, Ichihashi T. Nature,1993,363,603. 9 Thess A, Lee R, Nikolaev P, et al. Science,1996,273,483. 10 郭晓琦,白云起,白青子,等. 碳素,2018(2),40. 11 Behabtu N, Young C, Tsentalovich D, et al. Science,2013,339,182. 12 Janas D, Kreft S K,et al. Materials & Design,2017,116,16. 13 Zhao J, Zhang X,Di J, et al. Small,2010,6(22),2612. 14 Jakubinek M B, Johnson M B,et al. Carbon,2012,50(1),244. 15 Zhang M, Li M,Wang S, et al. Materials & Design,2017,117,37. 16 Liu P, Lam A, Fan Z, et al. Materials & Design,2015,87,600. 17 Zhong X H, Li Y L, et al. Advanced Materials,2010,22(6),692. 18 Di J, Zhang X,Yong Z, et al. Advanced Materials,2016,28,10529. 19 Janas D, Koziol K K. Nanoscale,2016,8(47),19475. 20 邢亚娟, 陈宏源, 陈名海, 等. 科学通报,2014,59(28-29),2840. 21 王珍珍, 李敏, 刘千立, 等. 复合材料学报,2016,33(10),44. 22 Barrera E, Shofner M, Corral E. Carbon nanotubes: science and applications,CRC Press,USA,2005. 23 Qian D, Dickey E C, Andrews R, et al. Applied Physics Letters,2000,76(20),2868 24 涂文斌, 柯黎明, 徐卫平.复合材料学报,2011,28(6),142. 25 李明川, 蒋立异, 刘婷婷, 等. 复合材料学报,2018,35(7),1889. 26 杨华, 潘强, 孙姣, 等. 真空与低温,2018,24(2),100. 27 Jin S G, KimY, Kim C.Composites Science and Technology,2013,87,224. 28 Wang J N, Luo X G,Wu T. Nature Communications,2014,5,3848 29 Zhang Rufan ,Zhang Yingying ,Wei Fei . Accounts of Chemical Research,2018,50(2),179. 30 Smitherman Jr D, Tether G. Space elevators. Technical report. NASA,2000. 31 张伟. 中国专利, 201310103153.4.2013. 32 Khatiwada S, Laughman J, Armada C, et al. In: Hypervelocity Impact Symposium. United States,2012. 33 Harris C, Shuart M, Gray H. A survey of emerging materials for revolutionary aerospace vehicle structures and propulsion systems. NASA,2002. 34 邹菁云,赵静娜,张骁. 材料导报:综述篇,2014,28(5),30. 35 Xu G, Zhao J, Li S, et al. Nanoscale,2011,3(10),4215 36 Lekawa-Raus A,Gizewski T, et al. Scripta Materialia,2016,131,112. 37 张伟波. 双壁碳纳米管薄膜的制备及其电磁屏蔽性能研究. 硕士学位论文, 江西理工大学,2015. 38 Micheli D, PastoreR, GradoniG, et al. Acta Astronaut,2013,88,61. 39 Jarosz P R, Shaukat A, Schauerman C M, et al. ACS Applied Materials & Interfaces,2012,4(2),1103. 40 Urper O,Cakmak Ipek, Karatepe N. Materials Letters,2018,97,223. 41 Kumar A, Zhou C. ACS Nano,2010,4,11. 42 Jiang J W, Wang J S. Journal of Applied Physics,2011,110(12),124319. 43 Janas D, Kozlol K K. Carbon,2013,59,457. 44 Yoon Y H, Song J W, et al. Advanced Materials,2007,19(23),4284. 45 李运泽, 魏传锋, 袁领双, 等.系统仿真学报,2005,17(6),1494. 46 Qin L, Wang X, Su G, et al. Scientific Reports,2016,6,21014. 47 Cola B A,Xu X F,Fishe R T S. Applied Physics Letters,2007,90(9),093513 . 48 Keller S, Zaghloul A. William Andrew, Elsevier,Boston,2014,pp.749. 49 Street K Jr, Miyoshi K. Application of carbon based nano-materials to aeronautics and space lubrication. Technical report. NASA,2007. 50 刘宇明, 刘向鹏, 童靖宇, 等. 航天器环境工程,2013,30(3),230. 51 Cao A Y, Zhang X F, Xu C L, et al. Solar Energy Materials and Solar Cells,2002,70,481. 52 Mizuno K, Ishii J, Kishida H, et al. PNAS,2009,106(15),6044. |
|
|
|