[1] Crawford D A.The production and evolution of plasma associated magnetic fields during hypervelocity impacts: implications for planetary paleomagnetism［D］. Brown University, 1992:52-73.

[2] Caswell R D, McBride N, Taylor A. Olympus end of life anomaly—A Perseid meteoroid impact event ［J］. International Journal of Impact Engineering, 1995, 17:139-150.

[3] Bourdeau R E. On the interaction between a spacecraft and an ionized medium［J］. Space Science Review, 1963, 1:719-728.

[4] Kissel J, Krueger F R. Ion formation by hypervelocity impact of dust particles and comparison with related techniques［J］. Appl Phy A, 1987, 42:69-85.

[5] Crawford D A, Schultz P H. The production and evolution of impact-generated magnetic fields［J］. International Journal of Impact Engineering, 1993, 14:205-216．

[6] Hood L L, Vickery A. Magnetic field amplification and generation in hypervelocity meteoroid impacts with application to lunar paleomagnetism［J］. Journal of Geophysics Research, 1984, 89(s1):C211-C223.

[7] Fechtig H, Grun E, Kissel J. Laboratory simulation［M］//Cosmic Dust. 1978:607-669.

[8] McDonnell J A M, McBride N, Gardner D J. The Leonid meteoroid stream: spacecraft interactions and effects［C］//Proc of 2nd Euro Conf on Space Debris. 1997:391-396.

[9] Crawford D A, Schultz P H. Laboratory investigations of impact—generated plasma［J］. Journal of Geophysics Research, 1991, 96:18807-18817．

[10] Akahoshi Y, Nakamura T, Fukushige S, et al. Influence of space debris impact on solar array under power generation［J］. International Journal of Impact Engineering, 2008, 35:1678-1682.

[11] Harano T, Machida Y, Fukushige S, et al. Preliminary study on sustained arc due to plasma excited by hypervelocity impact of space debris on the solar array coupon［J］. International Journal of Impact Engineering, 2006, 33:326-334.

[12] Toyoda K, Aso S, Kyoku T, et al. Proposal of a current regulative diode for power supply in sustained arc test［J］. IEEE Trans on Plasma Science, 2006, 34(5):1967-1972.

[13] Srnka L J, Martelli G, Newton G, et al. Magnetic field and shock effects and remanent magnetization in a hypervelocity impact experiment［J］. Earth and Planetary Science Lett, 1979, 42(1):127-137.

[14] Lai S T, Murad E, McNeil W J. Hazards of hypervelocity impacts on spacecraft［J］. J Spacecraft and Rockets, 2002, 39(1):106-114.

[15] Foschini L. Patterns of variability in γ-ray blazars［J］. Advances in Space Research, 2009, 43(7):1036-1044．

[16] Lambert M. Hypervelocity impacts and damage laws［J］. Advance in Space Research, 1997, 19(2):369-378．

[17] Tang Enling, Zhang Qingming, He Yuanhang, et al. Preliminary study on diagnostic techniques for transient plasma generated by hypervelocity impact［J］. Plasma Science and Technology, 2008, 10(6):735-738.

[18] Tang Enling, Zhang Qingming, Zhang Jian. Preliminary study on magnetic induction intensity induced by plasma during hypervelocity impact［J］. Chinese Journal of Aeronautics, 2009, 21:311-317.

[19] Tang Enling, Zhang Qingming, Ouyang Jiting. Fast diagnosis of transient plasma by Langmuir probe［J］. Journal of Beijing Institute of Technology, 2007, 16(3):375-378.

[20] 唐恩凌,唐伟富,相升海,等.超高速碰撞产生弱磁场的线圈测量系统［J］.强激光与粒子束, 2010, 22(5):1132-1136.(Tang Enling, Tang Weifu, Xiang Shenghai, et al. Coil measurement system for weak magnetic field generated by hypervelocity impact. High Power Laser and Particle Beams, 2010, 22(5):1132-1136)

[21] 唐恩凌, 张庆明, 张健.超高速碰撞LY12铝靶产生膨胀等离子体云的电导率测量［J］.强激光与粒子束, 2009, 21(2):297-300.(Tang Enling, Zhang Qingming, Zhang Jian. Conductivity measurement of an expanding plasma cloud generated by hypervelocity impact LY12 aluminum target. High Power Laser and Particle Beams, 2009, 21(2):297-300)