[1] [1] G. Galzerano, C. Svelto, E. Bava et al.. High-frequency-stability diode-pumped Nd:YAG lasers with the FM sidebands method and Doppler-free iodine lines at 532 nm［J］. Appl. Opt., 1999, 38(33): 6962～6966

[2] [2] N. Ohmae, S. Moriwaki, N. Mio et al.. Wideband and high-gain frequency stabilization of a 100-W injection-locked Nd:YAG laser for second-generation gravitational wave detectors［J］. Rev. Sci. Instrum., 2010, 81(7): 073105

[3] [3] M. L. Eickhoff, J. L. Hall. Optical frequency standard at 532 nm［J］. IEEE Trans. Instrumentation and Measurement, 1995, 44(2): 155～158

[4] [4] L. G. Kazovsky. Performance analysis and laser linewidth requirements for optical PSK heterodyne communications-systems［J］. J. Lightwave Technology, 1986, 4(4): 415～425

[5] [5] A. Arie, R. L. Byer. Frequency stabilization of the 1064-nm Nd-YAG lasers to Doppler-broadened lines of iodine［J］. Appl. Opt., 1993, 32(36): 7382～7386

[6] [6] Zhao Nanjing, Liu Wenqing, Zhang Yujun et al.. The fluorescence emission of water at upconversion of frequency by laser induced fluorescence［J］. Spectroscopy and Spectral Analysis, 2006, 26(6): 980～982

[7] [7] Zhang Bin, Long Xingwu, Liu Jianping et al.. Lamb-dip frequency-stabilized He-Ne laser with an integrated cavity made of zerodur (Ⅰ): structure and techniques［J］. Acta Optica Sinica, 2011, 31(8): 0814005

[8] [8] T. Day, E. K. Gustafson, R. L. Byer. Sub-hertz relative frequency stabilization of 2-diode laser-pumped Nd-YAG lasers locked to a Fabry-Perot-interferometer［J］. IEEE J. Quantum Electron., 1992, 28(4): 1106～1117

[9] [9] M. Bregant, G. Cantatore, F. Della Valle et al.. Frequency locking to a high-finesse Fabry-Perot cavity of a frequency doubled Nd:YAG laser used as the optical phase modulator［J］. Rev. Sci. Instrum., 2002, 73(12): 4142～4144

[10] [10] Yuan Dandan, Hu Shuling, Liu Honghai et al.. Research of laser frequency stabilization［J］. Laser & Optoelectronics Progress, 2011, 48(8): 081401

[11] [11] M. Musha, T. Kanaya, K. Nakagawa et al.. The short- and long-term frequency stabilization of an injection-locked Nd:YAG laser in reference to a Fabry-Perot cavity and an iodine saturated absorption line［J］. Opt. Commun., 2000, 183(1-4): 165～173

[12] [12] Meng Tengfei, Wu Yuelong, Ji Zhonghua et al.. Frequency stabilized diode laser based on cesium molecular saturated absorption spectroscopy［J］. Chinese J. Lasers, 2010, 37(5): 1182～1185

[13] [13] T. J. Quinn. Practical realization of the definition of the metre (1997)［J］. Metrologia, 1999, 36(3): 211～244

[14] [14] R. X. Guo, F. L. Hong, A. Onae et al.. Frequency stabilization of a 1319-nm Nd:YAG laser by saturation spectroscopy of molecular iodine［J］. Opt. Lett., 2004, 29(15): 1733～1735

[15] [15] L. S. Ma, L. Hollberg, J. H. Shirley et al.. Modulation transfer spectroscopy for stablizing laser［P］. U.S. Patent, 4590597, 1986-5-20

[16] [16] Zang Erjun, Cao Jianping, Li Ye et al.. 532 nm iodine molecular optical frequency standards［J］. Chinese J. Lasers, 2007, 34(2): 203～208

[17] [17] W. P. Deng, B. Gao, C. F. Cheng et al.. A frequency-stabilized difference frequency generation laser spectrometer for precise line profile studies in the midinfrared［J］. Rev. Sci. Instrum., 2008, 79(12): 123101

[18] [18] K. Nyholm, M. Merimaa, T. Ahola et al.. Frequency stabilization of a diode-pumped Nd:YAG laser at 532 nm to iodine by using third-harmonic technique［J］. IEEE Trans. Instrumentation and Measurement, 2003, 52(2): 284～287

[19] [19] J. Ye, L. Robertsson, S. Picard et al.. Absolute frequency atlas of molecular 1-2 lines at 532 nm［J］. IEEE Trans. Instrumentation and Measurement, 1999, 48(2): 544～549