[1] [1] FENG X K, CHEN H X, HUANG H Z, et al. A bond-free PPLN thin film ridge waveguide[J]. Optics Laser Technology, 2023, 162: 109298.

[2] [2] CHEN J K, GHASRI P, AGUILAR G, et al. An overview of clinical and experimental treatment modalities for port wine stains[J]. Journal of the American Academy of Dermatology, 2012, 67(2): 289-304.

[3] [3] INAGAKI K, OHKOSHI K, OHDE S, et al. Comparative efficacy of pure yellow (577-nm) and 810-nm subthreshold micropulse laser photocoagulation combined with yellow (561-577-nm) direct photocoagulation for diabetic macular edema[J]. Japanese Journal of Ophthalmology, 2015, 59(1): 21-28.

[4] [4] KAPOOR V, KARPOV V, LINTON C, et al. Solid state yellow and orange lasers for flow cytometry[J]. Cytometry Part A, 2008, 73A(6): 570-577.

[5] [5] BETZIG E, PATTERSON G H, SOUGRAT R, et al. Imaging intracellular fluorescent proteins at nanometer resolution[J]. Science, 2006, 313(5793): 1642-1645.

[7] [7] CHIN J C Y, WIZINOWICH P, WETHERELL E, et al. Keck II laser guide star AO system and performance with the TOPTICA/MPBC laser［C］//Adaptive Optics Systems V, SPIE Proceedings. Edinburgh, United Kingdom. SPIE, 2016: 254-272.

[8] [8] D’ORGEVILLE C, FETZER G J. Four generations of sodium guide star lasers for adaptive optics in astronomy and space situational awareness［C］//Adaptive Optics Systems V, SPIE Proceedings. Edinburgh, United Kingdom. SPIE, 2016: 236-253.

[9] [9] WEI K, LI M, JIANG C C, et al. LGS adaptive optics system with long-pulsed sodium laser on Lijiang 1.8 meter telescope 2014-2016 observation campaign［C］//Adaptive Optics Systems V, SPIE Proceedings. Edinburgh, United Kingdom. SPIE, 2016: 1614-1621.

[10] [10] ELLERBROEK B L, ADKINS S M, ANDERSEN D R, et al. TMT adaptive optics program status report［C］//SPIE Proceedings, Adaptive Optics Systems III. Amsterdam, Netherlands. SPIE, 2012: 84471 J.

[11] [11] GAO J, DAI X, ZHANG L, et al. All-solid-state continuous-wave yellow laser at 561 nm under in-band pumping[J]. Journal of the Optical Society of America B, 2013, 30(1)： 95-98.

[13] [13] SONG S, LIN H Y, SHI W J, et al. Small yellow-green Nd∶YAG/PPMgLN laser module at 561.3 nm[J]. Optik, 2021, 232: 166557.

[14] [14] GAYER O, SACKS Z, GALUN E, et al. Temperature and wavelength dependent refractive index equations for MgO-doped congruent and stoichiometric LiNbO3[J]. Applied Physics B, 2008, 91(2): 343-348.

[15] [15] MILLER G D, BYER R L. Periodically poled lithium niobate: modeling, fabrication, and nonlinear-optical performance［M］. 1998.

[16] [16] MIZUUCHI K, MORIKAWA A, SUGITA T, et al. Electric-field poling in Mg-doped LiNbO3[J]. Journal of Applied Physics, 2004, 96(11): 6585-6590.

[17] [17] BUZDY A, GLOS R, MAKKAI G, et al. Temperature-dependent terahertz time-domain spectroscopy study of Mg-doped stoichiometric lithium niobate[J]. Optical Materials Express, 2020, 10(4): 998.

[18] [18] MA L, FENG X K, CHEN H X, et al. Compact yellow-orange Nd∶YVO4/PPMgLN laser at 589 nm[J]. Optoelectronics Letters, 2023, 19(11): 641-645.

[19] [19] ZHU P F, LI B, LIU W Q, et al. All-solid-state continuous-wave frequency doubling Nd∶YAG/LBO laser with 8.2 W output power at 660 nm[J]. Optics and Spectroscopy, 2012, 113(5): 560-564.