[1] Raghunathan V, Borlaug D, Rice R R et al. Demonstration of a mid-infrared silicon Raman amplifier[J]. Optics Express, 15, 14355-14362(2007).
[2] Granados E, Spence D J, Mildren R P. Deep ultraviolet diamond Raman laser[J]. Optics Express, 19, 10857-10863(2011).
[3] Ding S, Wang P, Qing X et al. Analysis of actively Q-switched intracavity frequency-doubled solid-state yellow Raman lasers[J]. Applied Physics B, 104, 819-827(2011).
[4] Cheng P, Zhao J Q, Xu F et al. Diode-pumped mid-infrared YVO4 Raman laser at 2418 nm[J]. Applied Physics B, 124, 1-5(2017).
[5] Xu J J, Zhang X Y, Cong Z H et al. Tunable Nd3+∶YAG/KTiOAsO4 Raman lasers[J]. Chinese Journal of Lasers, 47, 0601002(2020).
[6] He Z X, Zhang P, Wu D et al. 1.7 μm tunable multi-wavelength Raman fiber laser based on amplified spontaneous emission pump[J]. Laser & Optoelectronics Progress, 57, 071403(2020).
[7] Cheng M Y, Duan Y M, Sun Y L et al. Research progress of Raman and frequency mixing for visible lasers based on vanadate crystals[J]. Laser & Optoelectronics Progress, 57, 071611(2020).
[8] Warrier A M, Lin J P, Pask H M et al. Highly efficient picosecond diamond Raman laser at 1240 and 1485 nm[J]. Optics Express, 22, 3325-3333(2014).
[9] Wang C, Cong Z H, Qin Z G et al. LD-side-pumped Nd∶YAG/BaWO4 intracavity Raman laser for anti-Stokes generation[J]. Optics Communications, 322, 44-47(2014).
[10] Grasiuk A Z, Kurbasov S V, Losev L L. Picosecond parametric Raman laser based on KGd(WO4)2 crystal[J]. Optics Communications, 240, 239-244(2004).
[11] Wei W, Zhang X Y, Wang Q P et al. Theoretical and experimental study on intracavity pumped SrWO4 anti-Stokes Raman laser[J]. Applied Physics B, 116, 561-568(2014).
[12] Wang C, Zhang X Y, Wang Q P et al. Extracavity pumped SrWO4 anti-stokes Raman lasers[J]. Chinese Journal of Lasers, 41, 0302008(2014).
[13] Wang C, Zhang X Y, Wang Q P et al. Extracavity pumped BaWO4 anti-Stokes Raman laser[J]. Optics Express, 21, 26014-26026(2013).
[14] Mildren R P, Coutts D W, Spence D J. All-solid-state parametric Raman anti-Stokes laser at 508 nm[J]. Optics Express, 17, 810-819(2009).
[15] Smetanin S N, Jelínek M, Kubeček V. Parametric Raman crystalline anti-Stokes laser at 503 nm with collinear beam interaction at tangential phase matching[J]. Applied Physics B, 123, 1-14(2017).
[16] Vermeulen N, Debaes C, Fotiadi A A et al. Stokes-anti-Stokes iterative resonator method for modeling Raman lasers[J]. IEEE Journal of Quantum Electronics, 42, 1144-1156(2006).
[17] Smetanin S N, Jelínek M, Tereshchenko D P et al. Extracavity pumped parametric Raman nanosecond crystalline anti-Stokes laser at 954 nm with collinear orthogonally polarized beam interaction at tangential phase matching[J]. Optics Express, 26, 22637-22649(2018).
[18] Yang C. All-solid-state picosecond multi-pulse pumped infrared wave stimulated Raman scattering[D](2020).
[19] Panarin A M, Strizhevskiĭ V L. Anti-Stokes stimulated Raman scattering of light by polaritons[J]. Soviet Journal of Quantum Electronics, 8, 964-970(1978).
[20] Boyd R W[M]. Nonlinear optics(2008).
[21] Li G[M]. Laser frequency conversion and expansion technology(2005).
[22] Gao X Q. Research on all-solid state picosecond pulse-train synchronously pumping broad-band stimulated Raman scattering effect[D](2018).
[23] Ma N, Chen M, Yang C et al. High-efficiency 50 W burst-mode hundred picosecond green laser[J]. High Power Laser Science and Engineering, 8, e1(2020).
[24] Gao X Q, Long M L, Meng C. Compact KGd(WO4)2 picosecond pulse-train synchronously pumped broadband Raman laser[J]. Applied Optics, 55, 6554-6558(2016).