[1] J Doyle, B Friedrich, R V Krems, et al.. Editorial: Quo vadis, cold molecules [J]. Eur Phys J D, 2004, 31(2): 149-164.
[2] L D Carr, D DeMille, R V Krems, et al.. Cold and ultracold molecules: science, technology and applications [J]. New J Phys, 2009,11(5): 055049.
[3] R V Krems, W C Stwalley, B Friedrich. Cold Molecules: Theory, Experiment, Applications [M]. Boca Raton: CRC Press, 2009.
[4] D S Jin, J Ye. Introduction to ultracold molecules: new frontiers in quantum and chemical physics [J]. Chemical Reviews, 2012, 112(9): 4801-4802.
[5] E S Shuman, J F Barry, D DeMille. Laser cooling of a diatomic molecule [J]. Nature, 2010, 467(7317): 820-823.
[6] J F Barry, E S Shuman, E B Norrgard, et al.. Laser radiation pressure slowing of a molecular beam [J]. Phys Rev Lett, 2012, 108(10):103002.
[7] J F Barry, D J McCarron, E B Norrgard, et al.. Magneto-optical trapping of a diatomic molecule [J]. Nature, 2014, 512(7514): 286-289.
[8] M T Hummon, M Yeo, B K Stuhl, et al.. 2D magneto-optical trapping of diatomic molecules [J]. Phys Rev Lett, 2013, 110(14):143001.
[9] V Zhelyazkova, A Cournol, T E Wall, et al.. Laser cooling and slowing of CaF molecules [J]. Phys Rev A, 2014, 89(5): 053416.
[10] Ma Yuchao, Zhang Limin, Zhuang Xiujuan, et al.. Calculation of the Franck-Condon factors for the C2 Σ+g ← B2 Σ+u transitions of CS+2 ions and comparison with related photodissocation spectra [J]. Acta Physica-Chimica Sinica, 2006, 22(12): 1532-1536.
[11] F Castano, Juan J de, E Martinez. The calculation of potential energy curves of diatomic molecules: the RKR method [J]. J Chm Educ, 1983, 60(2): 91-93.
[12] Liu Xueshen, Liu Xiaoyan, Zhou Zhongyuan, et al.. Numerical solution of one-dimensional time-independent Schr dinger equation by using Symplectic schemes [J]. Int J Quant Chem, 2000, 79(6): 343-349.
[13] V I Arnold. Mathematical Method of Classical Mechanics [M]. New York: Springer Press, 1978. 61-65.
[14] Qin Mengzhao, Zhu Wenjie. Construction of higher order Symplectic schemes by composition [J]. Computing, 1992, 47(3-4): 309-315.
[15] Kang Feng. Difference schemes for Hamiltonian formalism and symplectic geometry [J]. J Comput Math, 1986, 4 (3): 279-289.
[16] Feng Kang, Wu Huamo, Qin Mengzhao. Symplectic difference schemes for linear hamilton canonical systems [J]. J Comput Math,1990, 8(4): 371-380.
[17] Feng Kang, Wang Daoliu. A note on conservation laws of symplectic difference schemes for Hamiltonian systems [J]. J Comput Math, 1991, 9(3): 229-237.
[18] J Brown, A Carrington. Rotational Spectroscopy of Diatomic Molecules [M]. Cambdridge: Cambdridge University Press, 2003. 341.
[19] F A Jenkins, R Grinfeld. The specturm of MgF [J]. Phy Rev, 1934, 45(4): 229-233.
[20] M Pelegrini, C S Vivacqua, O Roberto- Neto, et al.. Radiative transition probabilities and lifetimes for the band systems A2Π—X2 Σ+ of the isovalent molecules BeF, MgF and CaF [J]. Brazilian Journal of Physics, 2005, 35(4A): 950-956.
[21] W J Childs, L S Goodman, I Renhorn. Radio- frequency optical double- resonance spectrum of SrF: the X 2 Σ+ state [J]. J Mol Spectrosc, 1981, 87(2): 522-533.
[22] J Schumann, D Wildman, A Gallagher. Emission of Mg-Xe discharge and the MgXe excimer band [J]. J Chem Phys, 1980, 72(11):6081-6084.
[23] O Nedelec, J Dufayard. Lifetimes of the MgH (MgD) and HgH(HgD) A2Π state excited by a pulsed dye laser [J]. J Chem Phys,1978, 69(5): 1833-1835.
[24] O Appelblad, L Klynning. Fourier transform spectroscopy of SrH: the A-X and B-X Band systems [J]. Physica Scripta, 1986, 33(5):415-419.
[25] T Pauchard, M Liu, O Launila, et al.. Time-resolved studies of the A2Π and B2 Σ states of SrH by laser spectroscopy [J]. J Mol Spectros, 2008, 247(1): 181-183.
[26] A E Parker. Band systems of MgCl, CaCl and SrCl [J]. Phys Rev, 1935, 47(5): 349-358.
[27] P J Dagdigian, H W Cruse, R N Zare. Radiative lifetime of the alkaline earth monohalides [J]. J Chem Phys, 1974, 60(6): 2330-2339.
[28] W W Jr, D M Jr, P H Kasai. ESR and optical spectroscopy of ScO, YO, and LaO in neon and argon matrices establishment of their ground electronic states [J]. J Chem Phys, 1967, 46(8): 3172-3184.
[29] J Shirley, C Scurlock, T Steimle. Molecular-beam optical Stark spectroscopy of ScO [J]. J Chem Phys, 1990, 93(3): 1568-1575.
[30] C H Douglass, H H Nelson, J K Rice. Spectra radiative lifetime and band oscillator strengths of the A1Π—X1Σ+ transition of BH [J]. J Chem Phys, 1989, 90(12): 6940-6948.
[31] L R Hunter, S K Peck, A S Greenspon, et al.. Prospects for laser cooling TlF [J]. Phys Rev A, 2012, 85(1): 012511.
[32] Zheng Gongjue, Dai Dapeng, Fang Yinfei, et al.. Balanced homodyne detector based on two- stage amplification [J]. Laser & Optoelectronics Progress, 2014, 51(4): 040401.
[33] Zheng Gongjue, Dai Dapeng, Fang Yinfei, et al.. Locking of optical transfer cavity based on PDH technique [J]. Laser & Optoelectronics Progress, 2014, 51(12): 040401.
[34] Qu Wancheng, Huang Yao, Guan Hua, et al.. 397 nm semiconductor laser stabilized with scanning transfer cavity [J]. Chinese J Lasers, 2011, 38(8): 0802008.
[35] Han Yashuai, Wen Xin, Bai Jiandong, et al.. Laser frequency stabilization of 1560 nm laser after after frequency doubling to 780 nm with a waveguide: radio-frequency frequency-modulation spectroscopy versus modulation transfer spectroscopy with Rb atoms [J]. Acta Optica Sinica, 2014, 34(5): 0530002.
[36] Ma Xiangchun, Zou Hongxin, Shen Yong, et al.. Study of digitized automatic phase locking based on field programmable gate array [J]. Acta Optica Sinica, 2011, 31(7): 0714003.
[38] Yuan Dandan, Hu Shuling, Liu Honghai, et al.. Research of laser frequency stabilization [J]. Laser & Optoelectronics Progress,2011, 48(8): 081401.