[1] T H JEYS, A BRAILOVE, A MOORADIAN. Sum frequency generation of sodium resonance radiation. Applied Optics, 28, 2588-2591(1989).

[2] M B DANAILOV. 589 nm light generation by intracavity mixing in a Nd：YAG laser. Journal of Applied Physics, 75, 8240-8242(1994).

[3] Yong BI, Zhipei SUN, Ying ZHANG et al. All-solid-state sum-frequency 589 nm Nd：YAG laser. Chinese Journal of Lasers, 5, 440(2003).

[4] T BAER. Large-amplitude fluctuation due to longitudinal-mode coupling in diode-pumped intracavity-doubled Nd：YAG laser. Journal of the Optical Society of America B, 3, 1175-1179(1986).

[5] A A SURIN, T E BORISENKO, S V LARIN. Generation of 14 W at 589 nm by frequency doubling of high-power CW linearly polarized Raman fiber laser radiation in MgO：sPPLT crystal. Optics Letters, 41, 2644-2647(2016).

[6] Yang LIU, Zhaojun LIU. Quasi-continuous-wave 589-nm radiation based on intracavity frequency-doubled Nd：GGG/BaWO4 Raman laser. Optics and Laser Technology, 81, 184-188(2016).

[7] Mengmeng LI, Fei YANG, Lanlan GAO. All solid-state cavity and frequency single longitudinal mode 593.5nm yellow laser. Chinese Journal of Lasers, 47, 0301003(2020).

[8] R BEGE. Watt-level second-harmonic generation at 589 nm with a PPMgO：LN ridge waveguide crystal pumped by a DBR tapered diode laser. Optics Letters, 41, 1530-1533(2016).

[9] Huadong LU, Kunchi PENG. Realization of the single-frequency and high power as well as frequency tuning of the laser by manipulating the nonlinear loss. Journal of Optics B-Quantum and Semiclassical Optics, 21, 171-176(2015).

[10] K WALLMEROTH, P PEUSER. High power， cw single-frequency TEM₀₀， diode-laser pmped Nd：YAG laser. Electronics Letters, 24, 1086-1088(1988).

[11] J J ZAYHOWSKI, A MOORADIAN. Frequency-modulated Nd：YAG Microchip Lasers. Optics Letters, 14, 618-620(1989).

[12] Xuejun SUN, Jiao WEI, Wenzhe WANG et al. Realization of a continuous frequency-tuning Ti：sapphire laser with an intracavity locked etalon. Chinese Optics Letters, 13, 071401(2015).

[13] Wei TAN, Xiaofang FU, Zhixin LI et al. The wavelength tunable 589 nm laser output based on singly resonant sum-frequency generation and the measurement of saturate fluorescence spectrum of sodium atom. Acta Physico Chimica Sinica, 62, 219-224(2013).

[14] Shiyong XIE, Xiaofu ZHANG, Chengliang YANG et al. Continuous-wave single-frequency 589 nm yellow laser generated from sum frequency of single-block non-planar ring cavity laser in periodically poled KTiOPO4 crystal. Acta Physico Chimica Sinica, 65, 84-90(2016).

[15] Lanlan GAO, Huiming TAN. LD-pumped all-solid-state single-frequency laser technology. Optical Electromechanical Information, 8-11(2002).

[16] A ABRAMOVICI. Minimal Nd：YAP laser configuration with single frequency output. Optics Communications, 61, 401-404(1987).

[17] Xiaojuan LIU, Lulian FU, Ranran ZHUO. Pulse LDA-pumped single-frequency Nd：YVO₄-KTP green laser using Brewster plate. Journal of Optoelectronics Laser, 17, 370-372(2006).

[18] Yizhe YUAN, Bin LI. Laser diode-pumped Nd：YAG crystals frequency summing 589 nm yellow laser. Optik, 127, 710-712(2016).

[19] A W TUCKER, M BIRNBAUM, C L FINCHER et al. Stimulated-emission cross-section at 1064 and 1342 nm in Nd：YVO4. Journal of Applied Physics, 48, 4907-4911(1977).

[20] Shiyong XIE, Xiaofu ZHANG. Continuous-wave single-frequency 589 nm yellow laser generated from sum-frequency of single-block non-planar ring cavity laser in periodically poled KTiOPO4 crystal. Acta Physico Chimica Sinica, 65, 094203(2016).

[21] J JUNGHANS, M KELLER, H WEBER. Laser resonators with polarizing elements-Eigenstates and eigenvalues of polarization. Applied Optics, 13, 2793-2798(1974).