[1] D L Elliott. Ultraviolet Laser Technology and Applications[M]. United States: Academic Press, 1995.

[2] W W Duley.UV Lasers: Effects and Applications in Materials Science[M]. Cambridge: Cambridge University Press, 2005.

[3] T Kuwamoto, K Honda, Y Takahashi, et al.. Magneto-optical trapping of Yb atoms using an intercombination transition[J]. Phys Rev A, 1999, 60(2): R745-R748.

[4] P Villwock, S Siol, Th Walther. Magneto-optical trapping of neutral mercury[J]. Eur Phys J D, 2011, 65(1-2): 251-255.

[5] F Y Loo, A Brusch, S Sauge, et al.. Investigations of a two-level atom in a magneto-optical trap using magnesium[J]. J Opt B: Quantum Semiclass Opt, 2004, 6(1): 81-85.

[6] M Eichenseer, A Y Nevsky, Ch Schwedes. Towards an indium single-ion optical frequency standard[J]. J Phys B: At Mol Opt Phys, 2003, 36(3): 553-557.

[7] C W Chou, D B Hume, J C J Koelemeij, et al.. Frequency comparison of two high-accuracy Al+ optical clocks[J]. Phys Rev Lett, 2010, 104(7): 070802.

[8] J L Hall, J Ye. Optical frequency standards and measurement[J]. IEEE Trans Instrum Meas, 2003, 52(2): 227-231.

[9] Liu Hongli. Study of Laser Spectroscopy and Laser Cooling of Neutral Mercury Atoms[D]. Shanghai: Shanghai Institute of Optics and Fine Mechcnics, Chinese Academy of Sciences, 2013. 29-30.

[10] G S He, S H Liu. Physics of Nonlinear Optics[M]. Singapore: World Scientific, 2003.

[11] Sun Guixia, Liu Tao, Qian Jinning, et al.. Tunable all-solid-state continuous wave intra-cavity frequency-doubled Nd:YVO4/LBO 671 nm ring laser[J]. Chinese J Lasers, 2013, 40(6): 0602011.

[12] E D Black. An introduction to Pound-Drever-Hall laser frequency stabilization[J]. Am J Phys, 2001, 69(1): 79-87.

[13] M Vainio, J E Bernard, L Marmet. Cavity-enhanced optical frequency doubler based on transmission-mode Hansch-Couillaud locking[J]. Appl Phys B, 2011, 104(4): 897-908.

[14] E K Sittig. Transmission parameters of thickness-driven piezoelectric transducers arranged in multilayer configurations[J]. IEEE Trans Sonics Ultrason, 1967, SU-14: 167-174.

[15] L S Fock, R S Tucker. Simultaneous reduction of intensity noise and distortion in semiconductor lasers by feedforward compensation[J]. Electron Lett, 1991, 27(14): 1297-1299.

[16] Wu Ying, Chen Dijun, Sun Yanguang, et al.. Research on optical chirp linearization technique of semiconductor lasers by an optoelectronic feedback loop[J]. Chinese J Lasers, 2013, 40(9): 0902001.

[17] T Petelski, M Fattori, G Lamporesi, et al.. Doppler-free spectroscopy using magnetically induced dichroism of atomic vapor: A new scheme for laser frequency locking[J]. Eur Phys J D, 2003, 22(2): 279-283.

[18] Shiqi Yin, Hongli Liu, Jun Qian, et al.. Observation and optimization of DAVLL spectra on the 1S0-3P1 transition of neutral mercury atom[J]. Opt Commun, 2012, 285(24): 5169-5174.

[19] Liu Hongli, Qian Jun, Xu Zhen, et al.. A frequency tuning and locking system of a deep UV laser for laser cooling of mercury atoms[J]. Chinese J Lasers, 2013, 40(9): 0902005.

[20] J P Toomey, D M Kane, M W Lee, et al.. Nonlinear dynamics of semiconductor lasers with feedback and modulation[J]. Opt Express, 2010, 18(16):16955-16972.

[21] Hongli Liu, Shiqi Yin, Qian Jun, et al.. Optimization of Doppler-free magnetically induced dichroic locking spectroscopy on the 1S0-3P1 transition of a neutral mercury atom[J]. J Phys B: At Mol Opt Phys, 2013, 46(8): 085005.