[1] Schall W O. Ablation Performance Experiments with Metal Seeded Polymers[C]. New York: Third International Symposium on Beam Energy Propulsion, 2005: 423-432.
[2] Sinko J E, Pakhomov A V. Delrin for Propulsion with CO2 Laser Carbon Doping Effects[C]. New York: Fifth International Symposium on Beam Energy Propulsion, 2008: 254-265.
[3] Jiao L, Cai J, Ma H, et al. Research on Applications of Rectangular Beam in Micro Laser Propulsion[J]. Applied Surface Science, 2014, 301: 481-487.
[4] Urech L, Lippert T. Designed Polymers for Laser-Based Micro Thrusters Correlation of Thrust with Material, Plasma and Shockwave Properties[C]. Bellingham: High-Power Laser Ablation V, Proceeding of SPIE, 2004, 5448: 52-64.
[5] Horisawa H, Sumida S. Yonamine H, et al. Thrust Generation Through Low Power Laser Metal Interaction for Space Propulsion Applications[J]. Vacuum, 2013,(88): 75-78.
[6] Ye Ji-Fei, Wu Wen-Tang. Effects of Target Thickness on Propulsion Performance in Laser Micro Confinement Ablation[C]. Shanghai: International Symposium on Photonics and Optoelectronics, 2012.
[7] Zheng Z Y, Gao H, Gao L, et al. Laser Plasma Propulsion Generation in Nanosecond Pulse Laser Interaction with Polyimide Film[J]. Applied Physics A, 2014,(115): 1439-1443
[8] Li Nan-Lei, Jin Xing. Numerical Simulation for Thrust Generation Process of Laser Ablated Polymer[C]. Wuhan: International Symposium on Photonics and Optoelectronics, 2011.
[9] Tsuruta H, Wang B, Wang Z, et al. Repetitive Pulse Performance of One-Micrometer Laser Ablation Propulsion onto Aluminum[J]. Journal of Propulsion and Power, 2014, 30(6): 1485-1489.
[10] 崔村燕, 洪延姬, 文明, 等. 水烧蚀激光推进性能初步分析[J]. 推进技术, 2010,31(2): 240-256. (CUI Cun-yan, HONG Yan-ji, WEN Ming, et al. Primary Analysis for Performance of Laser Propulsion with Water Propellant[J]. Journal of Propulsion Technology, 2010, 31(2): 240-256.)
[11] Li Nan-lei, Hong Yan-ji and Li Xiu-qian. Numerical Study of Thrust Generation in the Process of Laser Ablated Doped Polymer[C]. Ludwigsburg: Seventh International Symposium on Beamed Energy Propulsion, 2011.
[12] Yabe T, Nakagawa R, Yamaguchi M, et al. Simulation and Experiments on Laser Propulsion by Water Cannon Target[C]. Melville New York United States: First International Symposium on Beamed Energy Propulsion, 2003.
[13] John Sinko, Lisa Kodgis, Simon Porter, et al. Ablation of Liquids for Laser Propulsion with TEA CO2 Laser[C].Sendai Japan: Fourth International Symposium on Beamed Energy Propulsion, 2006: 308-318.
[14] Phipps C R, Luke J R, Wesley H. Laser-Powered, Multi-Newton Thrust Space Engine with Variable Specific Impulse[C]. Bellingham: High-Power Laser Ablation VII, 2008: 1-9.
[15] Phipps C R, Luke J R, Wesley H. Liquid-Fueled, Laser-Powered, N-class Thrust Space Engine with Variable Specific Impulse[C]. Melville: Fifth International Symposium on Beamed Energy Propulsion, 2008: 222-231.
[16] Lippert T, Urech L, Fardel R, et al. Materials for Laser Propulsion: “Liquid” Polymers[C]. Bellingham: High-Power Laser Ablation VII, 2008.
[17] Fardel R, Urech L, Lippert T, et al. Laser Ablation of Energetic Polymer Solutions: Effect of Viscosity and Fluence on the Splashing Behavior[J]. Applied Physics A, 2008, (109).
[18] Nakano M, Fujita K, Uchida S, Fundamental Experiments on Glycerin Propellant Laser Thruster[C]. Melville: Second International Symposium on Beamed Energy Propulsion, 2004: 139-145.
[19] 郑志远, 贺然, 董爱国, 等. 甘油的黏度对激光等离子体推进的影响[J]. 物理实验, 2012, 32(4): 7-9.
[20] Ye Ji-Fei, Wang Guang-Yu, Wang Dian-Kai. Measurement of Laser Ablation Micro Impulse Using the Torsion Pendulum Interferometry[C]. Nanchang: Second International Conference on Advanced Measurement and Test, 2011: 1078-1082
[21] 王广宇, 洪延姬. 微冲量测量的建模误差分析[J]. 推进技术, 2009,30(4): 509-512. (WANG Guang-yu, HONG Yan-ji. Modeling Error Analysis of Micro Impulse Measurements[J]. Journal of Propulsion Technology, 2009,30(4): 509-512.) * 收稿日期:2015-05-26;修订日期:2015-06-03。基金项目:装备预研项目(513200603);国家自然科学基金(11102234);激光推进及其应用国家重点实验室基础研究项目。作者简介:李南雷(1981—),男,博士,研究领域为激光推进技术。E-mail:linanlei010@163.com(编辑:史亚红)
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