[1] [1] NAMPOOTHIRI A, JONES AM, FOURCADE-DUTIN C, et al. Hollow-core optical fiber gas lasers (HOFGLAS): a review [Invited][J]. Optical Materials Express 2014, 2(7): 948-61.

[2] [2] MARCATILI EAJ, SCHMELTZER RA. Hollow metallic and dielectric waveguides for long distance optical transmission and lasers[J]. Bell System Technical Journal, 1964, 43(4): 1783-809.

[3] [3] SMITH PW. A waveguide gas laser[J]. Applied Physics Letters, 1971, 19(5): 132.

[4] [4] BRIDGES TJ, BURKHARDT EG, SMITH PW. CO2 waveguide lasers[J]. Applied Physics Letters, 1972, 20(10): 403-5.

[5] [5] LACHAMBRE J-L, MACFARLANE J, OTIS G, et al. A transversely RF-excited CO2 waveguide laser[J]. Applied Physics Letters, 1978, 32(10): 652-3.

[8] [8] PAYUROV AY, BODROV AI, KYUN VV, et al. Waveguide lasers of the LCD series and some features of their application[J]. St Petersburg Polytechnical University Journal Physics Mathematics, 2017, 3(1): 29-34.

[9] [9] IONIN AA. Electric discharge CO lasers in gas lasers:CRC Press, 2007.

[10] [10] WILLIAM F K, RAYMOND J, BEACH, et al. Resonance transition 795 nm rubidium laser[J]. Optics Letters, 2003, 28(23): 2336-8.

[11] [11] ZHDANOV BV, EHRENREICH T, KNIZE RJ. Highly efficient optically pumped cesium vapor laser[J]. Optics Communications, 2006, 260(2): 696-8.

[12] [12] ZWEIBACK J, KOMASHKO A, KRUPKE WF. Alkali vapor lasers[C]// Conference on High Energy/Average Power Lasers and Intense Beam Applications IV, 2010.

[14] [14] CREGAN RF, MANGAN BJ, KNIGHT JC, et al. Single-mode photonic band gap guidance of light in air[J]. Science, 1999, 285(5433): 1537-9.

[15] [15] BENABID F, KNIGHT J C, ANTONOPOULOS G, et al. Stimulated Raman scattering in Hydrogen-filled hollow-core photonic crystal fiber[J]. Science, 2002, 298(5592): 399-402.

[16] [16] OUZOUNOV DG, AHMADH FR, MULLER D, et al. Generation of megawatt optical solitons in hollow-core photonic band-gap fibers[J]. Science, 2003, 301(5640): 1702-4.

[17] [17] KNABE K, WU S, LIM J, et al. 10 kHz accuracy of an optical frequency reference based on (12)C2H2-filled large-core kagome photonic crystal fibers[J]. Optics Express, 2009, 17(18): 16017-26.

[18] [18] COUNY F, BENABID F, LIGHT PS. Subwatt threshold cw Raman fiber-gas laser based on H2-filled hollow-core photonic crystal fiber[J]. Physical Review Letters, 2007, 99(14): 143903.

[20] [20] COUNY F, BENABID F, ROBERTS PJ, et al. Generation and photonic guidance of multi-octave optical-frequency combs[J]. Science, 2007, 318(5853): 1118-21.

[22] [22] GRIVAS C. Optically pumped planar waveguide lasers, part I: fundamentals and fabrication techniques[J]. Progress in Quantum Electronics, 2011, 35(6): 159-239.

[23] [23] SNITZER E. Optical maser action of Nd+3 in a Barium crown glass[J]. Physical Review Letters, 1961, 7(12): 444-6.

[24] [24] ZEIDLER G. Optical waveguide technique with organic dye lasers[J]. Journal of Applied Physics, 1971, 42(2): 884-5.

[25] [25] YAJIMA H, KAWASE S, SEKIMOTO Y. Amplification at 1.06 μm using a Nd: glass thin-film waveguide[J]. Applied Physics Letters, 1972, 21(9): 407-9.

[26] [26] HANNA DC, LARGE AC, SHEPHERD DP, et al. A side-pumped Nd: YAG epitaxial waveguide laser[J]. Optics Communications, 1992, 91(3-4): 229-35.

[28] [28] YU AW, BETIN A, KRAINAK MA, et al. Highly efficient Yb: YAG master oscillator power amplifier laser transmitter for future space flight missions[J]. Advanced Solid-state Photonics, 2012.

[29] [29] JIA Y, CHEN F. Compact solid-state waveguide lasers operating in the pulsed regime: a review [Invited][J]. Chinese Optics Letters, 2019, 017(001): 73-95.

[30] [30] DEGNAN JJ. The waveguide laser: a review[J]. Applied Physics, 1976, 11(1): 1-33.

[31] [31] JONES AM, NAMPOOTHIRI A, RATANAVIS A, et al. Mid-infrared gas filled photonic crystal fiber laser based on population inversion[J]. Optics Express, 2011, 19(3): 2309-16.

[32] [32] LANCASTER DG, GROSS S, EBENDORFF-HEIDPRIEM H, et al. Efficient 2.9 μm fluorozirconate glass waveguide chip laser[J]. Optics Letters, 2013, 38(14): 2588-91.

[35] [35] GRIVAS C. Optically pumped planar waveguide lasers: part II: gain media, laser systems, and applications[J]. Progress in Quantum Electronics, 2016, 45-46: 3-160.