[1] 廖同庆, 等. 有限包层Bragg光纤模式的分类与特性研究［J］. 光学技术, 2014, 40( 2):167-171.

    LIAO Tongqing, et al. Classification and properties of modes in Bragg fibers with a finite number of H/L layers［J］. Optical Technique, 2014, 40(2):167-171.

[2] 刘道军. 无限包层Bragg光纤的传输模式研究［J］. 光学技术, 2016, 42(1): 65-69.

    LIU Daojun. Research on the transmission model of unlimited cladding Bragg fiber［J］. Optical Technique, 2016, 42(1):65-69.

[3] 任国斌, 等. 高折射率芯Bragg光纤的色散特性研究［J］. 物理学报, 2004, 53(6):1862-1867.

    REN Guobin, et al. Dispersion properties of high-index-core Bragg fibers［J］. Acta Physica Sinica. 2004, 53(6):1862-1867.

[4] 林晨曦. Bragg光纤带隙调控光传输特性与工艺制备［D］. 北京: 清华大学, 2007.

    LIN Chenxi. Characteristics of optical transmission with bandgap control in Bragg fiber and its fabrication［D］. Beijing: Tsinghua University, 2007.

[5] BURAK Temelkuran, et al. Wavelength-scalable hollow optical fibres with large photonic bandgaps for CO2 laser transmission［J］. Nature, 2002, 420:650-653.

[6] KURIKI K, et al. Hollow multilayer photonic bandgap fibers for NIR applications［J］. Optical Express, 2004, 12:1510-1517.

[7] G. Vienne, et al. First demonstration of air-silica Bragg fiber［C］∥Optical Fiber Communication Conference (OFC), Los Angeles, U.S.,2004, PDP25.

[8] TAKASHI Katagiri, et al. Photonic bandgap fiber with a silica core and multilayer dielectric cladding［J］. Optics Letters, 2004, 29( 6):557-559.

[9] MA Lin, et al. Nanotaper optics with Bragg-fiber structure［J］. APOC, Proc. of SPIE, 2006: 6351, 63510Z.

[10] YOEL Fink, et al. Guiding optical light in air using an all-dielectric structure［J］. Journal of Lightwave Technology, 1999, 17(11):2039-2041.

[11] DANIEL J. Gibson, et al. Extrusion of hollow waveguide preforms with a one-dimensional photonic band gap structure［J］. Journal of Applied Physics, 2004, 95(8):3895-3900.

[12] 任国斌, 等. 高折射率芯Bragg光纤的模式特征［J］. 光电子激光, 2004, 15(5):565-568.

    REN Guobin, et al. Mode characteristics of high-index-core Bragg fibers［J］. Journal of Optoelectronics·Laser, 2004, 15(5):565-568.