[1] R. W. F. Gross, J. F. Bott. Handbook of Chemical Laser［M］. Beijing: Science Press,1987. 453～483

[2] I. A. Fedorov. Continuous Wave Hydrogen Fluoride and Deuterium Fluoride Chemical Lasers［M］. Changsha: National University of Defense Technology Press, 2010. 128～135

[3] Jun Sung Park, Seung Wook Beak, Doyoung Byun. Variation of population inversion and gain characteristics with D2 injection angle in DF chemical laser cavity［J］. Int. J. Heat. Mass Tran., 2008, 51(1-2): 361～377

[4] Jun Sung Park, Seung Wook Beak. Numerical study of base effects on population inversion in DF chemical laser cavity［J］. Int. J. Heat. Mass Tran., 2006, 49(21-22): 4043～4057

[5] Zhou Bingkun, Gao Yizhi, Chen Tirong et al.. Principle of Lasers［M］. Beijing: National Defence Industrial Press, 2000. 172～177

[6] Yuan Shengfu. Theoretical Design of Latest Gain Generator for Continuous Wave DF/HF Chemical Lasers［D］. Changsha: National University of Defense Technology, 2002. 34～35

[7] Luo Wei, Yuan Shengfu, Lu Qisheng et al.. A method of measuring flow field temperature for HF/DF chemical laser［J］. Chinese J. Lasers, 2010, 37(3): 636～639

[8] Wang Hongyan, Yuan Shengfu, Li Qiang et al.. Chosing cavity axis for a discharge driven CW line-selected HF/DF chemical laser［J］. High Power Laser and Particle Beams, 2005, 18(8): 1257～1260

[9] Yuan Shengfu, Zhao Yijun, Hua Weihong et al.. Dependence of CW DF/HF chemical laser performance on the flowfield parameters［J］. Chinese J. Lasers, 2001, A28(5): 402～406

[10] I. A. Fedorov, Y. P. Maksimov, N. E. Tretyakov et al.. Spectral composition of radiation of supersonic CW chemical lasers: an HF laser［J］. Opt. Spectrosc., 2002, 93(6): 947～954

[11] R. A. Chodzko. Power extraction in CW HF/DF chemical laser［C］. Proceedings of the International Conference on Laser′85 Las Vegas, 1985. 629～640