[1] |
Steinmetz T, Wilken T, Araujo-hauck C, et al. Laser frequency combs for astronomical observations [J]. Science, 2008, 321(5894): 1335-1337. |
[2] |
Gattass R R, Mazur E. Femtosecond laser micromachining in transparent materials [J]. Nature Photonics, 2008, 2(4): 219-225. |
[3] |
Tam A C, Leung W P, Zapka W, et al. Laser-cleaning techniques for removal of surface particulates [J]. Journal of Applied Physics, 1992, 71(7): 3515-3523. |
[4] |
Betti R, Hurricane O A. Inertial-confinement fusion with lasers [J]. Nature Physics, 2016, 12(5): 435-448. |
[5] |
Fried N M, Irby P B. Advances in laser technology and fibre-optic delivery systems in lithotripsy [J]. Nature Reviews Urology, 2018, 15(9): 563-573. |
[6] |
Zuo J, Lin X. High-power laser systems [J]. Laser & Photonics Reviews, 2022, 16(5): 2100741. |
[7] |
Jauregui C, Limpert J, Tünnermann A. High-power fibre lasers [J]. Nature Pphotonics, 2013, 7(11): 861-867. |
[8] |
白振旭, 陈晖, 李宇琪, 等. 基于金刚石拉曼转换的光束亮度增强研究进展[J]. 红外与激光工程, 2021, 50(1): 20200098. |
Bai Zhenxu, Chen Hui, Li Yuqi, et al. Development of beam brightness enhancement based on diamond Raman conversion [J]. Infrared and Laser Engineering, 2021, 50(1): 20200098. (in Chinese) |
[9] |
Brauch U, Röcker C, Graf T, et al. High-power, high-brightness solid-state laser architectures and their characteristics [J]. Applied Physics B, 2022, 128(3): 58. |
[10] |
Shen D Y, Sahu J K, Clarkson W A. Highly efficient in-band pumped Er: YAG laser with 60 W of output at 1645 nm [J]. Optics Letters, 2006, 31(6): 754-756. |
[11] |
Ichikawa Hiromasa, Yamaguchi Kohki, Katsumata Tomo, et al. High-power and highly efficient composite laser with an anti reflection coated layer between a laser crystal and a diamond heat spreader fabricated by room-temperature bonding [J]. Optics Express, 2017, 25(19): 22797-22804. |
[12] |
张万儒, 粟荣涛, 李灿, 张嵩, 姜曼, 马鹏飞, 马阎星, 吴坚, 周朴. 窄线宽光纤激光振荡器研究进展(特邀)[J]. 红外与激光工程, 2022, 51(6): 20210879. |
Zhang Wanru, Su Rongtao, Li Can, et al . Research progress of narrow linewidth fiber laser oscillator (invited) [J]. Infrared and Laser Engineering, 2022, 51(6): 20210879. (in Chinese) |
[13] |
Wang Z, Wu H, Fan M, et al. High power random fiber laser with short cavity length: theoretical and experimental investigations [J]. IEEE Journal of Selected Topics in Quantum Electronics, 2015, 21(1): 0900506. |
[14] |
钟凯, 张献中, 徐德刚, 等. 全固态双波长激光器研究进展(特邀)[J]. 光电技术应用, 2022, 37(4): 13-26, 78. |
Zhong K, Zhang X, Xu D, et al. Progress of all-solid-state dual-wavelength lasers (invited) [J]. Electro-Optic Technology Application, 2022, 37(4): 13-26,78. (in Chinese) |
[15] |
Bai Z, Williams R J, Kitzler O, et al. Diamond Brillouin laser in the visible [J]. APL Photonics, 2020, 5(3): 031301. |
[16] |
Bai Z, Zhang Z, Wang K, et al. Comprehensive thermal analysis of diamond in a high-power Raman cavity based on FVM-FEM coupled method [J]. Nanomaterials, 2021, 11(6): 1572. |
[17] |
Ripin D J, Ochoa J R, Aggarwal R L, et al. 165-W cryogenically cooled Yb: YAG laser [J]. Optics Letters, 2004, 29(18): 2154-2156. |
[18] |
王辉华, 林龙信, 叶辛. 高功率板条激光技术现状与发展趋势[J]. 红外与激光工程, 2020, 49(7): 20190456. |
Wang Huihua, Lin Longxin, Ye Xin. Progress and tendency of high power slab lasers [J]. Infrared and Laser Engineering, 2020, 49(7): 20190456. (in Chinese) |
[19] |
Bromage J, Bahk S W, Begishev I A, et al. Technology development for ultraintense all-OPCPA systems [J]. High Power Laser Science and Engineering, 2019, 7: e4. |
[20] |
Bai Z, Chen H, Gao X, et al. Highly compact nanosecond laser for space debris tracking [J]. Optical Materials, 2019, 98: 109470. |
[21] |
尚建力, 王君涛, 彭万敬, 等. 二极管泵浦高能激光研究进展和展望[J]. 强激光与粒子束, 2022, 34: 011007. |
Shang Jianli, Wang Juntao, Peng Wanjing, et al. Research progress and prospects of laser diode pumped high-energy laser [J]. High Power Laser and Particle Beams, 2022, 34: 011007. (in Chinese) |
[22] |
Li S, Wang Y, Lu Z, et al. Hundred-Joule-level, nanosecond-pulse Nd: glass laser system with high spatiotemporal beam quality [J]. High Power Laser Science and Engineering, 2016, 4: e10. |
[23] |
Bai Z N, Bai Z X, Yang C, et al. High pulse energy, high repetition picosecond chirped-multi-pulse regenerative amplifier laser [J]. Optics & Laser Technology, 2013, 46: 25-28. |
[24] |
Jauregui C, Stihler C, Limpert J. Transverse mode instability [J]. Advances in Optics and Photonics, 2020, 12(2): 429-484. |
[25] |
李磊, 王建磊, 程小劲, 刘晶, 施翔春, 陈卫标. 低温重复率Yb: YAG 固体激光放大器[J]. 红外与激光工程, 2013, 42(5): 1170-1173. |
Li Lei, Wang Jianlei, Cheng Xiaojin, et al. Cryogenic Yb: YAG solid state pulsed laser amplifier [J]. Infrared and Laser Engineering, 2013, 42(5): 1170-1173. (in Chinese) |
[26] |
Sun L, Liu T, Fu X, et al. 1.57 times diffraction-limit high-energy laser based on a Nd: YAG slab amplifier and an adaptive optics system [J]. Chinese Optics Letters, 2019, 17(5): 051403. |
[27] |
何建国, 李明, 貊泽强, 等. 高功率板条激光介质的纵向强制对流换热技术[J]. 红外与激光工程, 2020, 49(9): 20200556 |
He Jianguo, Li Ming, Mo Zeqiang, et al. Study on longitudinal forced convection heat transfer for high power slab media [J]. Infrared and Laser Engineering, 2020, 49(9): 20200556. (in Chinese) |
[28] |
白振旭, 王雨雷, 吕志伟, 等. 基于布里渊放大串行激光组束研究进展[J]. 激光与光电子学进展, 2015, 52(11): 110004. |
Bai Zhenxu, Wang Yulei, Lv Zhiwei, et al. Research progress of serial laser beam combination based on stimulated Brillouin amplification [J]. Laser & Optoelectronics Progress, 2015, 52(11): 110004. (in Chinese) |
[29] |
白振旭, 杨学宗, 陈晖, 等. 高功率金刚石激光技术研究进展(特邀)[J]. 红外与激光工程, 2020, 49(12): 20201076 |
Bai Zhenxu, Yang Xuezong, Chen Hui, et al. Research progress of high-power diamond laser technology (Invited) [J]. Infrared and Laser Engineering, 2020, 49(12): 20201076. (in Chinese) |
[30] |
陈义. 非共线布里渊串行放大激光组束研究[D]. 哈尔滨: 哈尔滨工业大学, 2016. |
Chen Yi. Research on laser beam combination based on non-collinear Brillouin serial amplification[D]. Harbin: Harbin Institute of Technology, 2016. (in Chinese) |
[31] |
McNaught S J, Asman C P, Injeyan H, et al. 100-kW coherently combined Nd: YAG MOPA laser array[C]//Frontiers in Optics, 2009: FThD2. |
[32] |
周朴, 粟荣涛, 马阎星, 等. 激光相干合成的研究进展: 2011—2020[J]. 中国激光, 2021, 48(4): 0401003. |
Zhou Pu, Su Rongtao, Ma Yanxing, et al. Review of coherent laser beam combining research progress in the past decade [J]. Chinese Journal of Lasers, 2021, 48(4): 0401003. (in Chinese) |
[33] |
刘小溪, 王学锋, 王军龙, 等. 光纤激光器外腔型光谱组束研究[J]. 中国激光, 2018, 45(8): 0801009. |
Liu Xiaoxi, Wang Xuefeng, Wang Junlong, et al. External cavity spectral beam combining of fiber lasers [J]. Chinese Journal of Lasers, 2018, 45(8): 0801009. (in Chinese) |
[34] |
Liu Zejin, Jin Xiaoxi, Su Rongtao, et al. Development status of high power fiber lasers and their coherent beam combination [J]. Science China Information Sciences, 2019, 62: 41301. |
[35] |
Cui Can, Wang Yulei, Lu Zhiwei, et al. Demonstration of 2.5 J, 10 Hz, nanosecond laser beam combination system based on non-collinear Brillouin amplification [J]. Optics Express, 2018, 26(25): 32717-32727. |
[36] |
崔璨, 王月, 王雨雷, 等. 非线性光学激光合束技术研究进展[J]. 强激光与粒子束, 2023, 35: 041006. |
Cui Can, Wang Yue, Wang Yulei, et al. Research progress on nonlinear optics laser beam combining technology [J]. High Power Laser and Particle Beams, 2023, 35: 041006. (in Chinese) |
[37] |
Alavipanah S K, Matinfar H R, Rafiei E A, et al. Criteria of selecting satellite data for studying land resources [J]. Desert, 2010, 15(2): 83-102. |
[38] |
Vatnik I D, Churkin D V, Babin S A, et al. Cascaded random distributed feedback Raman fiber laser operating at 1.2 μm [J]. Optics Express, 2011, 19(19): 18486-18494. |
[39] |
Bai Z, Williams R J, Kitzler O, et al. 302 W quasi-continuous cascaded diamond Raman laser at 1.5 microns with large brightness enhancement [J]. Optics Express, 2018, 26(16): 19797-19803. |
[40] |
杨成奥, 张一, 尚金铭, 等. 2~4 μm中红外锑 半导体激光器研究进展(特邀)[J]. 红外与激光工程, 2020, 49(12): 163-171. |
Yang Chengao, Zhang Yi, Shang Jinming, et al. Research progress of 2-4 μm mid-infrared antimonide semiconductor lasers (Invited) [J]. Infrared and Laser Engineering, 2020, 49(12): 20201075. (in Chinese) |
[41] |
陈毅, 刘高佑, 王瑞雪, 等. 非线性晶体应用于中长波红外固体激光器的研究进展[J]. 人工晶体学报, 2020, 49(08): 1379-1395. |
Chen Yi, Liu Gaoyou, Wang Ruixue, et al. Research progress of nonlinear crystal applied in mid-and long-wave infrared solid-state laser [J]. Journal of Synthetic Crystals, 2020, 49(8): 1379-1395. (in Chinese) |
[42] |
尤崴, 杨学宗, 陈卫标, 等. 589 nm激光钠导星技术研究综述(特邀)[J]. 光电技术应用, 2021, 36(5): 1-14, 22. |
You Wei, Yang Xuezong, Chen Weibiao, et al. Review of 589 nm sodium laser guide stars (invited) [J]. Electro-Optic Technology Application, 2021, 36(5): 1-14, 22. (in Chinese) |
[43] |
白振旭, 高嘉, 赵臣, 等. 基于非线性频率变换的长波红外激光器研究进展[J]. 光学学报, 2023, 43(3): 0314001. |
Bai Zhenxu, Gao Jia, Zhao Chen, et al. Research progress of long-wave infrared lasers based on nonlinear frequency conversion [J]. Acta Optica Sinica, 2023, 43(3): 0314001. (in Chinese) |
[44] |
Sutherland R L. Handbook of Nonlinear Optics[M]. 2nd ed. Boca Raton: CRC Press, 2003. |
[45] |
Boyd G D, Kleinman D A. Parametric interaction of focused gaussian light beams [J]. Journal of Applied Physics, 1968, 39(8): 3597-3639. |
[46] |
Pavel C̆, Jelı́nková H, Zverev P G, et al. Solid state lasers with Raman frequency conversion [J]. Progress in Quantum Electronics, 2004, 28(2): 113-143. |
[47] |
Bai Zhenxu, Zhao Chen, Gao Jia, et al. Optical parametric oscillator with adjustable pulse width based on KTiOAsO4 [J]. Optical Materials, 2023, 136: 113506. |
[48] |
Wang Y, Luther-davies B, Chuang Y H, et al. Highly efficient conversion of picosecond Nd laser pulses with the use of group-velocity-mismatched frequency doubling in KDP [J]. Optics Letters, 1991, 16(23): 1862-1864. |
[49] |
Budni P A, Pomeranz L A, Lemons M L, et al. Efficient mid-infrared laser using 1.9-µm-pumped Ho: YAG and ZnGeP2 optical parametric oscillators [J]. Journal of the Optical Society of America B, 2000, 17(5): 723-728. |
[50] |
焦亚东, 贾志旭, 郭晓慧, 等. 中红外玻璃光纤材料及拉曼激光光源研究进展(特邀)[J]. 红外与激光工程, 2023, 52(5): 20230228. |
Jiao Yadong, Jia Zhixu, Guo Xiaohui, et al. Progress on mid-infrared glass optical fiber materials and Raman laser source (invited) [J]. Infrared and Laser Engineering, 2023, 52(5): 20230228. (in Chinese) |
[51] |
Spillane S M, Kippenberg T J, Vahala K J. Ultralow-threshold Raman laser using a spherical dielectric microcavity [J]. Nature, 2002, 415(6872): 621-623. |
[52] |
Piper J A, Pask H M. Crystalline Raman lasers [J]. IEEE Journal of Selected Topics in Quantum Electronics, 2007, 13(3): 692-704. |
[53] |
Bloembergen N, Bret G, Lallemand P, et al. Controlled stimulated Raman amplification and oscillation in hydrogen gas [J]. IEEE Journal of Quantum Electronics, 1967, 3(5): 197-201. |
[54] |
Chen Hui, Bai Zhenxu, Zhao Chen, et al. Numerical simulation of long-wave infrared generation using an external cavity diamond raman laser [J]. Frontiers in Physics, 2021, 9: 671559. |
[55] |
Kitzler O, Mckay A, Spence D J, et al. Modelling and optimization of continuous-wave external cavity Raman lasers [J]. Optics Express, 2015, 23(7): 8590-8602. |
[56] |
Ma Shihui, Tu Heng, Lu Dazhi, et al. Efficient Raman red laser with second-order stokes effect of diamond crystal [J]. Optics Communications, 2021, 478: 126399. |
[57] |
Williams R J, Spence D J, Lux O, et al. High-power continuous-wave Raman frequency conversion from 1.06 µm to 1.49 µm in diamond [J]. Optics Express, 2017, 25(2): 749-757. |
[58] |
李牧野, 杨学宗, 孙玉祥, 等. 单频连续波金刚石拉曼激光器研究进展(特邀)[J]. 红外与激光工程, 2022, 51(06): 20210970. |
Li Muye, Yang Xuezong, Sun Yuxiang, et al. Single-frequency continuous-wave diamond Raman laser (invited) [J]. Infrared and Laser Engineering, 2022, 51(6): 20210970. (in Chinese) |
[59] |
白振旭, 陈晖, 张展鹏, 等. 百瓦级1.2/1.5 μm双波长金刚石拉曼激光器(特邀)[J]. 红外与激光工程, 2021, 50(12): 20210685. |
Bai Zhenxu, Chen Hui, Zhang Zhanpeng, et al. Hundred-watt dual-wavelength diamond Raman laser at 1.2/1.5 μm (invited) [J]. Infrared and Laser Engineering, 2021, 50(12): 20210685. (in Chinese) |
[60] |
Sheng Q, Li R, Lee A J, et al. A single-frequency intracavity Raman laser [J]. Optics Express, 2019, 27(6): 8540-8553. |
[61] |
Supradeepa V R, Feng Y, Nicholson J W. Raman fiber lasers [J]. Journal of Optics, 2017, 19(2): 023001. |
[62] |
崔淑珍, 曾鑫, 程鑫, 杨学宗, 冯衍. 基于级联拉曼激光倍频的10 W黄光光纤激光器[J]. 中国激光, 2021, 48(16): 1601006. |
Cui Shuzhen, Zeng Xin, Cheng Xin, et al. Generation of 10 W yellow fiber laser by frequency doubling of cascaded raman laser [J]. Chinese Journal of Lasers, 2021, 48(16): 1601006. (in Chinese) |
[63] |
Islam M N. Raman amplifiers for telecommunications [J]. IEEE Journal of Selected Topics in Quantum Electronics, 2002, 8(3): 548-559. |
[64] |
Feng Y, Taylor L R, Calia D B. 25 W Raman-fiber-amplifier-based 589 nm laser for laser guide star [J]. Optics Express, 2009, 17(21): 19021-19026. |
[65] |
Williams R J, Kitzler O, Bai Z, et al. High power diamond Raman lasers [J]. IEEE Journal of Selected Topics in Quantum Electronics, 2018, 24(5): 1602214. |
[66] |
Mckay A, Spence D J, Coutts D W, et al. Diamond-based concept for combining beams at very high average powers [J]. Laser & Photonics Review, 2017, 11(3): 1600130. |
[67] |
王聪. 晶体拉曼放大器和反斯托克斯激光器的理论与实验研究[D]. 济南: 山东大学, 2014. |
Wang Cong. The theoretical and experimental studies of crystalline Raman amplifier and anti-Stokes laser[D]. Jinan: Shandong University, 2014. (in Chinese) |
[68] |
Hellwarth R W. Theory of stimulated Raman scattering [J]. Physical Review, 1963, 130(5): 1850-1852. |
[69] |
Wang C S. Theory of stimulated Raman scattering [J]. Physical Review, 1969, 182(2): 482-494. |
[70] |
Shen Y R, Bloembergen N. Theory of stimulated brillouin and raman scattering [J]. Physical Review, 1965, 137(6A): 1787-1805. |
[71] |
丁双红. 全固态拉曼激光器理论与实验研究[D]. 济南: 山东大学, 2006. |
[72] |
王聪, 吕冬翔. 晶体拉曼放大器的理论解析[J]. 红外与激光工程, 2018, 47(11): 1105007. |
Wang Cong, Lv Dongxiang. Theoretical analysis on crystalline Raman amplifier [J]. Infrared and Laser Engineering, 2018, 47(11): 1105007. (in Chinese) |
[73] |
Krylov V, Rebane A, Erni D, et al. Stimulated Raman amplification of femtosecond pulses in hydrogen gas [J]. Optics Letters, 1996, 21(24): 2005-2007. |
[74] |
叶震寰, 楼祺洪, 董景星, 等. 高功率KrF激光后向拉曼压缩的实验研究[J]. 中国激光, 2003, 30(3): 223-226. |
Ye Z, Lou Q, Dong J, et al. Experimental research on backward SRS pumped by high power KrF laser [J]. Chinese Journal of Lasers, 2003, 30(3): 223-226. (in Chinese) |
[75] |
Hanna D C, Pointer D J, Pratt D J. Stimulated Raman-scattering of picosecond light-pulses in hydrogen, deuterium, and methane [J]. IEEE J Quantum Electron, 1983, 22(2): 332-336. |
[76] |
Trutna W R, Park Y K, Byer R L. Dependence of Raman gain on pump laser bandwidth [J]. IEEE J Quantum Electron, 1979, 15(7): 648-655. |
[77] |
Bischel W K, Dyer M J. Temperature-dependence of the raman linewidth and line shift for the Q(1) and Q(0) transitions in normal and para-H2 [J]. Physical Review A, 1986, 33(5): 3113-3123. |
[78] |
Culver W H, Vanderslice J T A , Townsend V W T. Controlled generation of intense light pulses in reverse-pumped Raman lasers [J]. Applied Physics Letters, 1968, 12(5): 189-190. |
[79] |
Hooper W P, Frick G M, Michael B P. Using backward Raman scattering from coupled deuterium cells for wavelength shifting [J]. Optical Engineering, 2009, 48(8): 084302. |
[80] |
Zhou Dongjian, Guo Jingwei, Zhou Canhua, et al. Backward raman scattering and amplification based on dual raman cells [J]. Chinese Journal of Lasers, 2016, 43(4): 0402006. (in Chinese) |
[81] |
Chang R S F, Djeu N. Amplification of a diffraction-limited Stokes beam by a severely distorted pump [J]. Optics Letters, 1983, 8(3): 139-141. |
[82] |
Stappaerts E A, Long W H, Komine H. Gain enhancement in Raman amplifiers with broad band pumping [J]. Optics Letters, 1980, 5(1): 4-6. |
[83] |
雷博, 楼棋洪, 董景星, 等. 高功率同轴抽运宽带拉曼放大[J]. 中国激光, 2001, 28(4): 289-292 |
Lei Bo, Lou Qihong, Dong Jingxing, et al. Broadband Raman amplification with coaxal laser pumping [J]. Chinese Journal of Lasers, 2001, 28(4): 289-292. (in Chinese) |
[84] |
Stegeman R, Rivero C, Stegeman G, et al. Raman gain measurements in bulk glass samples [J]. Journal of the Optical Society of America B, 2005, 22(9): 1861-1867. |
[85] |
楼祺洪, 宁东, 董景星. 斜入射泵浦宽带拉曼放大[J]. 光学学报, 1998, 18(9): 1203-1207. |
Lou Qihong, Ning Dong, Dong Jinxing. Wideband Raman amplification with tilted pumping beam [J]. Acta Optica Sinica, 1998, 18(9): 1203-1207. (in Chinese) |
[86] |
Hill K E, New G, Rodgers P A, et al. The influence of noise and angular dispersion during short pulse Raman amplification [J]. Optics Communications, 1992, 87(5-6): 315-322. |
[87] |
Duncan M D, Mahon R, Reintjes J, et al. Parametric raman gain suppression in D2 and H2 [J]. Optics Letters, 1986, 11(12): 803-805. |
[88] |
Chang R, Lehmberg R, Duignan M, et al. Raman beam cleanup of a severely aberrated pump laser [J]. IEEE Journal of Quantum Electronics, 1985, 21(5): 477-487. |
[89] |
薛峰. 基于晶体拉曼放大技术的单纵模589 nm激光器研究[D]. 济南: 山东大学, 2018. |
Xue Feng. Studies on single longitudinal mode 589 nm laser based on crystalline Raman amplifier[D]. Jinan: Shangdong University, 2018. (in Chinese) |
[90] |
Goldhar J, Taylor M, Murray J. An efficient double-pass Raman amplifier with pump intensity averaging in a light guide [J]. IEEE Journal of Quantum Electronics, 1984, 20(7): 772-785. |
[91] |
Szatmári S, Schäfer F P. Generation of input signals for ArF amplifiers [J]. Journal of the Optical Society of America B, 1989, 6(10): 1877-1883. |
[92] |
Glownia J H, Kaschke M, Sorokin P P. Amplification of 193-nm femtosecond seed pulses generated by third-order, nonresonant, difference-frequency mixing in xenon [J]. Optics Letters, 1992, 17(5): 337-339. |
[93] |
Kong H J, Yoon J W, Beak D H, et al. Beak, et al. Laser fusion driver using stimulated Brillouin scattering phase conjugate mirrors by a self-density modulation [J]. Laser Part Beams, 2007, 25(2): 225-238. |
[94] |
陈金宝, 郭少锋. 高能固态激光器技术路线分析[J]. 中国激光, 2013, 40(6): 69-75. |
Chen Jinbao, Guo Shaofeng. Review on technical approaches of high energy solid-state-lasers [J]. Chinese Journal of Lasers, 2013, 40(6): 0602006. (in Chinese) |
[95] |
Mu Jie, Jing Feng, Wang Xiao, et al. Error control of piston and tilt based on SPGD in coherent beam combination [J]. Chinese Journal of Lasers, 2014, 41(6): 0602002. |
[96] |
Chen Y, Lu Z, Wang Y, et al. Phase matching for noncollinear Brillouin amplification based on controlling of frequency shift of Stokes seed [J]. Optics Letters, 2014, 39(10): 3047-3049. |
[97] |
Wang Y, Cui C, Lu Z, et al. Beam spatial intensity modi-fication based on stimulated Brillouin amplification [J]. Optics Express, 2022, 30(20): 35792-35806. |
[98] |
Jacobs R R, Goldhar J, Eimerl D, et al. High-efficiency energy extraction in backward-wave Raman scattering [J]. Applied Physics Letters, 1980, 37(3): 264-266. |
[99] |
Mandl A, Holmes R, Flusberg A, et al. High-gain, high-efficiency stimulated Raman amplification with beam clean-up [J]. Journal of Applied Physics, 1989, 66(10): 4625-4634. |
[100] |
Basov N G, Grasyuk A Z, Karev Y I, et al. Hydrogen Raman laser for efficient coherent summation of nanosecond optical pulses [J]. Soviet Journal of Quantum Electronics, 1979, 9(6): 780-781. |
[101] |
Shaw M J, Partanen J P, Owadano Y, et al. High-power forward Raman amplifiers employing low-pressure gases in light guides. II. Experiments [J]. Journal of the Optical Society of America B: Optical Physics, 1986, 3(10): 1466-1475. |
[102] |
Partanen J P, Shaw M J. High-power forward Raman amplifiers employing low-pressure gases in light guides. I. Theory and applications [J]. Journal of the Optical Society of America B: Optical Physics, 1986, 3(10): 1374-1389. |
[103] |
Li Z, Huang W, Cui Y, et al. High-efficiency, high peak-power, narrow linewidth 1.9 μm fiber gas Raman amplifier [J]. Journal of Lightwave Technology, 2018, 36(17): 3700-3706. |
[104] |
Chen Y, Wang Z, Li Z, et al. Ultra-efficient Raman amplifier in methane-filled hollow-core fiber operating at 1.5 μm [J]. Optics Express, 2017, 25(17): 20944-20949. |
[105] |
Raghunathan V, Borlaug D, Rice R R, et al. Demonstration of a mid infrared silicon Raman amplifier [J]. Optics Express, 2007, 15(22): 14355-14362. |
[106] |
Lisinetskii V A, Orlovich V A, Rhee H, et al. Efficient Raman amplification of low divergent radiation in barium nitrate crystal [J]. Applied physics B, 2008, 91(2): 299-303. |
[107] |
Yakovlev V V, Petrov G I, Hao F Z, et al. Stimulated Raman scattering: old physics, new applications [J]. Journal of Modern Optics, 2009, 56(18-19): 1970-1973. |
[108] |
Buganov O, Bus'Ko D, Grabtchikov A, et al. Raman ampli-fication in KGW crystal at femtosecond pumping[C]//European Conference on Lasers and Electro-Optics and the European Quantum Electronics Conference, 2009. |
[109] |
Cong W, Cong Z, Liu Z, et al. Theoretical and experimental investigation of an efficient pulsed barium tungstate Raman amplifier at 1180 nm [J]. Optics Communications, 2014, 313(4): 80-84. |
[110] |
张文会, 丁双红, 丁泽, 等. 1064 nm纳秒脉冲激发的PbWO4固态拉曼放大器[J]. 中国激光, 2014, 41(05): 0502011. |
Zhang Wenhui, Ding Shuanghong, Ding Ze, et al. A PbWO4 solid-state raman amplifier excited by 1064 nm nanosecond pulses [J]. Chinese Journal of Lasers, 2014, 41(5): 0502011. (in Chinese) |
[111] |
Mckay A, Mildren R P, Coutts D W, et al. SRS in the strong-focusing regime for Raman amplifiers [J]. Optics Express, 2015, 23(11): 15012-15020. |
[112] |
刘兆军. 基于晶体拉曼技术的钠导星激光实现研究结题报告[R]. 北京: 国家自然科学基金委, 2018. |
[113] |
徐洋, 陈檬, 李政委, 等. 钒酸钇晶体皮秒拉曼放大器特性的研究[J]. 中国激光, 2013, 40(10): 1002005. |
Xu Yang, Chen Meng, Li Zhengwei, et al. Research of picosecond raman amplifier in YVO4 crystal [J]. Chinese Journal of Lasers, 2013, 40(10): 1002005. (in Chinese) |
[114] |
Grigsby F B, Peng D, Downer M C. Chirped-pulse Raman amplification for two-color, high-intensity laser experiments [J]. Journal of the Optical Society of America B, 2009, 25(3): 780-782. |
[115] |
Kulagin O V, Gorbuno I A, Sergeev A M, et al. Picosecond Raman compression laser at 1530 nm with aberration compensation [J]. Optics Letters, 2013, 38(17): 3237-3240. |
[116] |
Men S, Liu Z, Cong Z, et al. Single-frequency CaWO4 Raman amplifier at 1178 nm [J]. Optics Letters, 2015, 40(4): 530-533. |
[117] |
Liu Z, Rao H, Cong Z, et al. Single-frequency BaWO4 Raman MOPA at 1178 nm with 100-ns pulse pump [J]. Crystals, 2019, 9(4): 185. |
[118] |
郝鑫, 尹思宇, 张宗达, 等. 金刚石NV色心的制备及应用(特邀)[J]. 光电技术应用, 2022, 37(01): 1-9+57. |
Hao Xin, Yin Siyu, Zhang Zongda, et al. Preparation and application of nitrogen vacancy color center in diamond (invited) [J]. Electro-Optic Technology Application, 2022, 37(1): 1-9, 57. (in Chinese) |
[119] |
白振旭, 陈晖, 丁洁, 等. 基于空间光腔的高功率布里渊频率梳[J]. 中国激光, 2022, 49(04): 0415001. |
Bai Zhenxu, Chen Hui, Ding Jie, et al. High-power brillouin frequency comb based on free-space optical cavity [J]. Chinese Journal of Lasers, 2022, 49(4): 0415001. (in Chinese) |
[120] |
白振旭, 陈晖, 蔡云鹏, 等. 金刚石拉曼振荡器实现级联布里渊激光输出[J]. 红外与激光工程, 2022, 51(11): 20220660. |
[121] |
白振旭, 陈晖, 朱智涵, 等. 金刚石拉曼振荡器首次实现结构光束输出[J]. 中国激光, 2022, 49(21): 2116002. |