[1] Shen Y R. The principles of nonlinear optics[M]. New York: Wiley-Interscience, 188-192(1984).
[2] Damzen M J, Vlad V, Mocofanescu A et al[M]. Stimulated Brillouin scattering: fundamentals and application, 33-36(2003).
[3] Bai Z X, Wang Y L, Lü Z W et al. High compact, high quality single longitudinal mode hundred picoseconds laser based on stimulated Brillouin scattering pulse compression[J]. Applied Sciences, 6, 29-37(2016).
[5] Liu Z H, Wang Y L, Bai Z X et al. Pulse compression to one-tenth of phonon lifetime using quasi-steady-state stimulated Brillouin scattering[J]. Optics Express, 26, 23051-23060(2018).
[6] Yuan D P, Xu J, Liu Z et al. High resolution stimulated Brillouin scattering lidar using Galilean focusing system for detecting submerged objects[J]. Optics Communications, 427, 27-32(2018).
[7] Shi J, Ouyang M, Gong W et al. A Brillouin lidar system using F-P etalon and ICCD for remote sensing of the ocean[J]. Applied Physics B, 90, 569-571(2008).
[8] Liu D H, Xu J F, Li R S et al. Measurements of sound speed in the water by Brillouin scattering using pulsed Nd: YAG laser[J]. Optics Communications, 203, 335-340(2002).
[9] Popescu A, Schorstein K, Walther T. A novel approach to a Brillouin-LIDAR for remote sensing of the ocean temperature[J]. Applied Physics B, 79, 955-961(2004).
[11] Park S, Cha S, Oh J et al. Coherent beam combination using self-phase locked stimulated Brillouin scattering phase conjugate mirrors with a rotating wedge for high power laser generation[J]. Optics Express, 24, 8641-8646(2016).
[12] Tsubakimoto K, Yoshida H, Miyanaga N. High-average-power green laser using Nd: YAG amplifier with stimulated Brillouin scattering phase-conjugate pulse-cleaning mirror[J]. Optics Express, 24, 12557-12564(2016).
[13] Zhu Z H, Gao W, Mu C Y et al. Reversible orbital angular momentum photon-phonon conversion[J]. Optica, 3, 212-217(2016).
[14] Shi J, Chen X, Ouyang M et al. Theoretical investigation on the threshold value of stimulated Brillouin scattering in terms of laser intensity[J]. Applied Physics B, 95, 657-660(2009).
[15] Bespalov V G. Stasel'Ko D I. Spatial-temporal coherence of Stokes radiation under conditions of stimulated Brillouin scattering compression in liquids[J]. Soviet Journal of Quantum Electronics, 15, 1649-1651(1985).
[16] Wait P C, Newson T P. Measurement of Brillouin scattering coherence length as a function of pump power to determine Brillouin linewidth[J]. Optics Communications, 117, 142-146(1995).
[17] Zhang L, Zhang D, Shi J L et al. Investigations on coherence of stimulated Brillouin scattering excited by a single-mode-pulsed laser[J]. Applied Physics B, 109, 137-141(2012).
[18] Shi J L, Tang Y J, Wei H J et al. Temperature dependence of threshold and gain coefficient of stimulated Brillouin scattering in water[J]. Applied Physics B, 108, 717-720(2012).
[20] Park H, Lim C, Yoshida H et al. Measurement of stimulated Brillouin scattering characteristics in heavy fluorocarbon liquids and perfluoropolyether liquids[J]. Japanese Journal of Applied Physics, 45, 5073-5075(2006).
[21] Yao Q J[M]. A course in optics, 38-40(1989).
[22] Zhang L, Zhang D, Yang Z et al. Experimental investigation on line width compression of stimulated Brillouin scattering in water[J]. Applied Physics Letters, 98, 221106(2011).
[23] Born M, Wolf E[M]. Principles of optics, 466-467(1999).
[24] Goodman J W. Statistical optics[M]. New York: John Wiley & sons, 158-163(1985).
[25] Thompson B J, Wolf E. Two-beam interference with partially coherent light[J]. Journal of the Optical Society of America, 47, 895-902(1957).
[26] Jiang X M, Zhao J J, Huang W S[M]. Advanced optics, 163-186(1996).