[6] Shen D Y, Sahu J K, Clarkson W A. High-power widely tunable Tm: fibre lasers pumped by an Er, Yb co-doped fibre laser at 1.6 µm[J]. Optics Express, 2006, 14(13): 6084-6090.
[7] Slobodtchikov E, Moulton P F, EfficientFrith G., high[1] power, Tm-doped silica fiber laser[C]//Advanced Solid[1] State Photonics 2007, January 28-31, 2007, Vancouver, Canada. Washington, D. C: Optica Publishing Group, 2007: MF2.
[8] Moulton P F, Rines G A, Slobodtchikov E V, et al. Tm-doped fiber lasers: fundamentals and power scaling [J]. IEEE Journal of Selected Topics in Quantum Electronics, 2009, 15(1): 85-92.
[9] Hu Z Y, Yan P, Xiao Q R, et al. 227-W output all[1] fiberized Tm-doped fiber laser at 1908 nm[J]. Chinese Physics B, 2014, 23(10): 104206.
[10] Liu J, Shi H, Liu C, et al. High-power narrow-linewidth thulium-doped all-fiber MOPA[C]//Conference on Lasers and Electro-Optics/Pacific Rim. Optical Society of America, 2015: 27A1_3.
[11] Yin K, Zhu R Z, Zhang B, et al. 300 W-level,wavelength-widely-tunable,all-fiber integrated thulium[1] doped fiber laser[J]. Optics Express, 2016, 24(10): 11085-11090.
[12] 刘茵紫, 邢颍滨, 廖雷, 等 . 530 W 全光纤结构连续掺铥光纤激光器[J]. 物理学报, 2020, 69(18): 184209. Liu Y Z, Xing Y B, Liao L, et al. 530 W all-fiber continuous-wave Tm-doped fiber laser[J]. Acta Physica Sinica, 2020, 69(18): 184209.
[13] 杨昌盛, 陈丹, 赵齐来, 等 . 2.0 μm 波段掺铥连续单频光纤激光器的研究进展 [J]. 中 国 激 光 , 2017, 44(2): 0201006. Yang C S, Chen D, Zhao Q L, et al. Research progress of 2.0 μm-band Tm-doped continuous wave single[1] frequency fiber lasers[J]. Chinese Journal of Lasers, 2017, 44(2): 0201006.
[14] McComb T S, Sims R A, Willis C C C, et al. High[1]power widely tunable thulium fiber lasers[J]. Applied Optics, 2010, 49(32): 6236-6242.
[15] Guo C Z, Shen D Y, Long J Y, et al. High-power and widely tunable Tm-doped fiber laser at 2 μm[J]. Chinese Optics Letters, 2012, 10(9): 091406.
[16] Chen S X, Jung Y, Alam S U, et al. Ultra-wideband operation of a tunable thulium fibre laser offering tunability from 1679—1992 nm[C]∥2017 European Conference on Optical Communication (ECOC), September 17-21, 2017, Gothenburg, Sweden. New York: IEEE Press, 2017.
[17] Li Z, Alam S U, Jung Y, et al. All-fiber, ultra[1]wideband tunable laser at 2 μm[J]. Optics Letters, 2013, 38(22): 4739-4742.
[18] Yin K, Zhang B, Xue G, et al. High-power all-fiber wavelength-tunable thulium doped fiber laser at 2 μm[J]. Optics Express, 2014, 22(17): 19947-19952.
[19] Wang X, Jin X X, Zhou P, et al. High power, widely tunable, narrowband superfluorescent source at 2 μm based on a monolithic Tm-doped fiber amplifier[J]. Optics Express, 2015, 23(3): 3382-3389.
[20] Chen X, Dai D Z, Zhang Y, et al. Wavelength-flexible thulium-doped fiber laser based on digital micromirror array[J]. Micromachines, 2020, 11(12): 1036.
[21] Liu F, Liu P, Feng X, et al. Tandem-pumped, tunable thulium-doped fiber laser in 2.1 μm wavelength region[J]. Optics Express, 2019, 27(6): 8283-8290.
[22] Hardy L A, Fried N M. Comparison of first-generation (1908 nm) and second-generation (1940 nm) thulium fiber lasers for ablation of kidney stones[J]. Optical Engineering, 2019, 58(9): 096101.
[23] Chollet F, Goedgebuer J P, Porte H, et al. Electrooptic narrow linewidth wavelength tuning and intensity modulation of an erbium fiber ring laser[J]. IEEE Photonics Technology Letters, 1996, 8(8): 1009-1011.
[24] Wang F, Shen D Y, Fan D Y, et al. Spectral narrowing of cladding-pumped high-power Tm-doped fiber laser using a volume Bragg grating-pair[J]. Applied Physics Express, 2010, 3(11): 112701.
[25] Tao M M, Huang Q J, Yang P L, et al. Narrow linewidth CW amplification of a Tm-doped double-clad fiber MOPA system[J]. Optik, 2014, 125(3): 1141-1143.
[26] 刘江, 刘晨, 师红星, 等 . 342 W 全光纤结构窄线宽连续掺铥光纤激光器[J]. 物理学报, 2016, 65(19): 194209. Liu J, Liu C, Shi H X, et al. 342 W narrow-linewidth continuous-wave thulium-doped all-fiber laser[J]. Acta Physica Sinica, 2016, 65(19): 194209.
[27] 白燕, 延凤平, 冯亭, 等 . 基于保偏掺铥光纤饱和吸收体的2μm波段超窄线宽光纤激光器 [J]. 中国激光 , 2019, 46(1): 0101003. Bai Y, Yan F P, Feng T, et al. Ultra-narrow-linewidth fiber laser in 2 μm band using saturable absorber based on PM-TDF[J]. Chinese Journal of Lasers, 2019, 46(1): 0101003.
[28] Cook J, Roumayah P, Shin D J, et al. Narrow linewidth 80 W tunable thulium-doped fiber laser[J]. Optics & Laser Technology, 2022, 146: 107568.
[29] Shen D Y, Pearson L, Wang P, et al. Broadband Tm[1]doped superfluorescent fiber source with 11 W single[1]ended output power[J]. Optics Express, 2008, 16(15): 11021-11026.
[30] Yu G Y, Chang J, Wang Q P, et al. A theoretical model of thulium-doped silica fiber’s ASE in the 1900 nm waveband[J]. Optoelectronics Letters, 2010, 6(1): 45-47.
[31] Hu Z Y, Yan P, Liu Q, et al. High-power single-stage thulium-doped superfluorescent fiber source[J]. Applied Physics B, 2015, 118(1): 101-107.
[32] Khamis M A, Ennser K. Wide broadband ASE source based on thulium-doped fibre for 2 µm wavelength region [C]∥5th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS), February, 2017, Porto, Portugal. [S.l.: s.n.], 2017: 141-146.
[33] Aubrecht J, Peterka P, Honzátko P, et al. Broadband thulium-doped fiber ASE source[J]. Optics Letters, 2020, 45(8): 2164-2167.
[34] Michalewska Z, Michalewski J, Nawrocki J. Swept[1]source OCT[J]. Retina Today, 2013: 50-56.
[35] Pal D, Sen R, Pal A. Design of all-fiber laser at 1.95 µmfor soft tissue surgery[C]∥National Laser Symposium (NLS-24), December 2-5, 2015, Post Cat, Indore. Indore: Raja Ramanna Centre for Advanced Technology (RRCAT), 2015.
[36] Sypin V, Volkov A, Myasnikov D, et al. QCW thulium
fiber laser for medical application[C]∥2016 International Conference Laser Optics (LO), June 27-July 1, 2016, St. Petersburg, Russia. New York: IEEE Press, 2016: S1-10.
[37] Pal D, Sen R, Pal A. Design of all‐fiber thulium laser in CW and QCW mode of operation for medical use[J]. Physica Status Solidi C, 2017, 14(1/2): 1600127.
[38] Pal D, Chowdhury S D, Sen R, et al. QCW thulium fiber laser at 1.94 µm for kidney stone fragmentation[C]∥ National Laser Symposium (NLS-27), December 3-6, 2018, Post Cat, Indore. Indore: Raja Ramanna Centre for Advanced Technology (RRCAT).
[39] Limongelli J R, Allee E, Bieniek M, et al. A 564 W QCW thulium fiber oscillator pumped at 793 nm[C]∥Advanced Solid State Lasers, October 13-16, 2020, Washington, D. C., United States. Washington, D. C.: Optica Publishing Group, 2020: JTu5A.4.
[40] Eichhorn M, Jackson S D. High-pulse-energy actively Q[1]switched Tm3+-doped silica 2 μm fiber laser pumped at 792 nm[J]. Optics Letters, 2007, 32(19): 2780-2782.
[41] Willis C C C, Shah L, Baudelet M, et al. High-energy Q-switched Tm3+-doped polarization maintaining silica fiber laser[J]. Proceedings of SPIE, 2010, 7580: 758003.
[42] Stutzki F, Jansen F, Jauregui C, et al. 2.4 mJ, 33 W Q[1]switched Tm-doped fiber laser with near diffraction[1] limited beam quality[J]. Optics Letters, 2013, 38(2): 97-99.
[43] Li L, Zhang B, Yin K, et al. 1 mJ nanosecond all-fiber thulium-doped fiber laser at 2.05 μm[J]. Optics Express, 2015, 23(14): 18098-18105.
[44] Romano C, Jaouën Y, Tench R E, et al. kW pulsed nanosecond TDFL with direct modulation[J]. Proceedings of SPIE, 2019, 10897: 1089708.
[45] Grzes P, Swiderski J. Gain-switched 2- μm fiber laser system providing kilowatt peak-power mode-locked resembling pulses and its application to supercontinuum generation in fluoride fibers[J]. IEEE Photonics Journal, 2018, 10(1): 1500408.
[46] Liu S L, Dou Z Y, Zhang B, et al. High repetition rate gain-switched thulium-doped fiber laser pumped by 1.6 μm noise-like pulses[J]. Optics & Laser Technology, 2021, 138: 106856.
[47] Kadwani P, Modsching N, Sims R A, et al. Q-switched thulium-doped photonic crystal fiber laser[J]. Optics Letters, 2012, 37(10): 1664-1666.
[48] López-Estopier R, Camarillo-Avilés A, Bello-Jiménez M, et al. Q-switched mode locking noise-like pulse generation from a thulium-doped all-fiber laser based on nonlinear polarization rotation[J]. Results in Optics, 2021, 5: 100115.
[49] Wang M, Liu M Q, Chen Y W, et al. Stable noise-like pulse generation in all-PM mode-locked Tm-doped fiber laser based on NOLM[J]. Chinese Optics Letters, 2021, 19(9): 091402.
[50] Fried N M. Thulium fiber laser lithotripsy: an in vitro analysis of stone fragmentation using a modulated 110- watt Thulium fiber laser at 1.94 µm[J]. Lasers in Surgery and Medicine, 2005, 37(1): 53-58.
[51] Fried N M. High-power laser vaporization of the canine prostate using a 110 W Thulium fiber laser at 1.91 μm[J]. Lasers in Surgery and Medicine, 2005, 36(1): 52-56.
[52] Fried N M, Murray K E. High-power thulium fiber laser ablation of urinary tissues at 1.94 μm[J]. Journal of Endourology, 2005, 19(1): 25-31.
[53] Blackmon R L, Irby P B, Fried N M. Thulium fiber laser lithotripsy using tapered fibers[J]. Lasers in Surgery and Medicine, 2010, 42(1): 45-50.
[54] Blackmon R L, Fried N M, Irby P B. Enhanced thulium fiber laser lithotripsy using micro-pulse train modulation[J]. Journal of Biomedical Optics, 2012, 17(2): 028002.
[55] Traxer O, Keller E X. Thulium fiber laser: the new player for kidney stone treatment? A comparison with Holmium: YAG laser[J]. World Journal of Urology, 2020, 38(8): 1883-1894.
[56] Corrales M, Traxer O. Initial clinical experience with the new thulium fiber laser: first 50 cases[J]. World Journal of Urology, 2021, 39(10): 3945-3950.
[57] Taratkin M, Azilgareeva C, Korolev D, et al. Prospective single-center study of SuperPulsed thulium fiber laser in retrograde intrarenal surgery: initial clinical data[J]. Urologia Internationalis, 2022, 106(4): 404-410.
[58] Enikeev D, Grigoryan V, Fokin I, et al. Endoscopic lithotripsy with a SuperPulsed thulium-fiber laser for ureteral stones: a single-center experience[J]. International Journal of Urology, 2021, 28(3): 261-265.
[59] 林宇, 刘敏秋, 欧阳德钦, 等 . 基于掺铥光纤激光器的体外碎石实验探究[J]. 中国激光, 2022, 49(1): 0101015. Lin Y, Liu M Q, Ouyang D Q, et al. Exploration of thulium-doped fiber lasers in lithotripsy in vitro[J]. Chinese Journal of Lasers, 2022, 49(1): 0101015.
[60] Rice P, Somani B K. A systematic review of thulium fiber laser: applications and advantages of laser technology in the field of urology[J]. Research and Reports in Urology, 2021, 13: 519-527.
[61] Kronenberg P, Traxer O. The laser of the future: reality and expectations about the new thulium fiber laser-a systematic review[J]. Translational Andrology and Urology, 2019, 8(Suppl 4): S398-S417.
[62] Hardy L A, Kennedy J D, Wilson C R, et al. Analysis of thulium fiber laser induced bubble dynamics for ablation of kidney stones[J]. Journal of Biophotonics, 2017, 10(10): 1240-1249.
[63] 胡卫国, 李建兴 . 泌尿系结石的激光治疗现状[J]. 临床外科杂志, 2020, 28(2): 183-185. Hu W G, Li J X. Advances in laser techniques for stone treatment[J]. Journal of Clinical Surgery, 2020, 28(2): 183-185.
[64] 刘敏, 高小峰 . 铥光纤激光碎石基础研究和临床应用进展[J]. 中华泌尿外科杂志, 2021, 42(1): 75-78Liu M, Gao X F. Advances in fundamental research and clinical application of Thulium fiber laser lithotripsy[J]. Chinese Journal of Urology, 2021, 42(1): 75-78.
[65] Schembri M, Sahu J, Aboumarzouk O, et al. Thulium fiber laser: the new kid on the block[J]. Turkish Journal of Urology, 2020, 46(Supp. 1): S1-S10.
[66] 张航, 肖乐, 邹洪, 等 . SpyGlass 直视化系统在胆管疾病诊断和治疗中的应用[J]. 中国内镜杂志, 2019, 25(2): 1-5. Zhang H, Xiao L, Zou H, et al. Application of SpyGlass direct visualization system in diagnosis and treatment of biliary diseases[J]. China Journal of Endoscopy, 2019, 25 (2): 1-5.
[67] 孙明, 王宏光, 王曼彤, 等 . SpyGlass DS 胆道镜在肝内胆管结石中的应用分析[J]. 中国内镜杂志, 2021, 27(5): 78-83. Sun M, Wang H G, Wang M T, et al. Application of SpyGlass DS choledochoscope in intrahepatic bile duct stones[J]. China Journal of Endoscopy, 2021, 27(5): 78-83.
[68] 徐雯, 苗龙, 王正峰, 等 . SpyGlassTM DS 直视化系统在胆道疾病诊疗中的应用[J]. 临床肝胆病杂志, 2020, 36 (11): 2626-2629. Xu W, Miao L, Wang Z F, et al. Application of SpyGlassTM DS direct visualization system in the diagnosis and treatment of biliary tract diseases[J]. Journal of Clinical Hepatology, 2020, 36(11): 2626-2629.
[69] 邹莹莹, 郭彦东, 顾红祥, 等 . SpyGlass 在胆胰疾病中的应用[J]. 现代消化及介入诊疗, 2020, 25(6): 812-815. Zou Y Y, Guo Y D, Gu H X, et al. Application of SpyGlass in biliary and pancreatic diseases[J]. Modern Digestion & Intervention, 2020, 25(6): 812-815.
[70] Mizrahi M, Khoury T, Wang Y, et al.“Apple Far from the Tree”: comparative effectiveness of fiberoptic single[1] operator cholangiopancreatoscopy (FSOCP) and digital SOCP (DSOCP)[J]. HPB, 2018, 20(3): 285-288.
[71] Pal D, Paul A, Shekhar N K, et al. COM stone dusting and soft tissue ablation with Q-switched thulium fiber laser[J]. IEEE Journal of Selected Topics in Quantum Electronics, 2019, 25(1): 7100808.