[1] Cui Y L, Zhou Z Y, Huang W et al. Anti-resonant hollow-core fibers based 4.3-μm carbon dioxide lasers[J]. Acta Optica Sinica, 39, 1214002(2019).

[2] Huang W, Cui Y L, Li Z X et al. Research on 1.7 μm fiber laser source based on stimulated Raman scattering of hydrogen in hollow-core fiber[J]. Acta Optica Sinica, 40, 0514001(2020).

[3] Shilin N, Yingchun G. Review of UV laser and its applications in micromachining[J]. Opto-Electronic Engineering, 44, 1169-1179(2017).

[4] Wang L. Research on advantages of UV laser in semiconductor wafer cutting[J]. Equipment for Electronic Products Manufacturing, 39, 13-16(2010).

[5] Wan Y, Gebert F, Wübbena J B et al. Precision spectroscopy by photon-recoil signal amplification[J]. Nature Communications, 5, 3096(2014).

[6] Ludlow A D, Boyd M M, Ye J et al. Optical atomic clocks[J]. Reviews of Modern Physics, 87, 637-701(2015).

[7] Häffner H, Hänsel W, Roos C F et al. Scalable multiparticle entanglement of trapped ions[J]. Nature, 438, 643-646(2005).

[8] Britton J W, Sawyer B C, Keith A C et al. Engineered two-dimensional Ising interactions in a trapped-ion quantum simulator with hundreds of spins[J]. Nature, 484, 489-492(2012).

[9] Song G H, Yao C L, Wang Y H et al. -11-25[P]. plating method of precise dielectric film reflector: CN204903941U.(2015).

[10] Li C, Feng Z C, Cao N. Development of deep ultraviolet laser Raman spectrometer[J]. Bulletin of the Chinese Academy of Sciences, 26, 589-592(2011).

[11] Huang B K, An H Y, Fan F T. Mini UV Raman spectrometer[J]. The Journal of Light Scattering, 29, 348-353(2017).

[12] Wang Z M. A novel UV resonance Raman spectrometer with continuous tunability between 217 and 400 nm[J]. International Instruments, 9, 23-26(1986).

[13] Dragomir A. McInerney J G, Nikogosyan D N, et al. Two-photon absorption properties of commercial fused silica and germanosilicate glass at 264 nm[J]. Applied Physics Letters, 80, 1114-1116(2002).

[14] Lancry M, Poumellec B. UV laser processing and multiphoton absorption processes in optical telecommunication fiber materials[J]. Physics Reports, 523, 207-229(2013).

[15] Skuja L, Hosono H, Hirano M. Laser-induced color centers in silica[J]. Proceedings of SPIE, 4347, 155-168(2001).

[16] Colombe Y, Slichter D H, Wilson A C et al. Single-mode optical fiber for high-power, low-loss UV transmission[J]. Optics Express, 22, 19783-19793(2014).

[17] Marciniak C D, Ball H B. Hung A T H, et al. Towards fully commercial, UV-compatible fiber patch cords[J]. Optics Express, 25, 15643-15661(2017).

[18] Gao S F, Wang Y Y, Wang P. Research progress on hollow-core anti-resonant fiber and gas Raman laser technology[J]. Chinese Journal of Lasers, 46, 0508014(2019).

[19] Hong Y F, Wang Y Y, Ding W et al. Research progress on polarization maintaining hollow core fiber[J]. Acta Photonica Sinica, 48, 1148010(2019).

[20] Xia C M, Zhou G Y. Progress and prospect of microstructured optical fibers[J]. Laser & Optoelectronics Progress, 56, 170603(2019).

[21] Pang L, Zhang H J, Ning D. Research progress of ultraviolet pure silica hollow core microstructure optical fiber[J]. Optical Communication Technology, 42, 29-32(2018).

[22] Gao S F, Wang Y Y, Ding W et al. Hollow-core negative-curvature fiber for UV guidance[J]. Optics Letters, 43, 1347-1350(2018).

[23] Yu F, Cann M, Brunton A et al. Single-mode solarization-free hollow-core fiber for ultraviolet pulse delivery[J]. Optics Express, 26, 10879-10887(2018).

[24] Marcatili E A J, Schmeltzer R A. Hollow metallic and dielectric waveguides for long distance optical transmission and lasers[J]. Bell System Technical Journal, 43, 1783-1809(1964).

[25] Stratton J A. Electromagnetic theory[M]. New York: McGraw-Hill Companies, 524(1941).

[26] Jasion G T, Hayes J R, Wheeler N V et al. Fabrication of tubular anti-resonant hollow core fibers: modelling, draw dynamics and process optimization[J]. Optics Express, 27, 20567-20582(2019).