[1] T M Monro, D J Richardson, P J Bennett. Developing holey fibers for evanescent field devices[J]. Electron Lett, 1999, 35(14): 1188-1189.
[2] Y L Hoo, W Jin, H L Ho, et al.. Evanescent-wave gas sensing using microstructure fiber [J]. Opt Eng, 2002, 41(1): 8-9.
[3] Yao Jianquan, Wang Ran, Miao Yinping, et al.. Novel photonic functional devices based on liquid-filling microstructured optical fibers[J]. Chinese J Lasers, 2013, 40(1): 0101002.
[5] S Smolka, M Barth, O Benson. Highly efficient fluorescence sensing with hollow core photonic crystal fibers[J]. Opt Express. 2007, 15(20): 12783-12791.
[6] Y L Hoo, W Jin, J Ju, et al.. Numerical investigation of a depressed-index core photonic crystal fiber for gas sensing[J]. Sensor Actuat B-Chem, 2009, 139(2): 460-465.
[8] X Yu, Y C Kwok, N A Khairudin, et al.. Absorption detection of cobalt (Ⅱ) ions in an index-guiding microstructured optical fiber[J]. Sensor Actuat B-Chem, 2009, 137(2): 462-466.
[9] C Martelli, J Canning, D Stocks, et al.. Water-soluble porphyrin detection in a pure-silica photonic crystal fiber[J]. Opt Lett, 2006, 31(14): 2100-2102.
[10] J Park, S Lee, S Kim, et al.. Enhancement of chemical sensing capability in a photonic crystal fiber with a hollow high index ring defect at the center[J]. Opt Express, 2011, 19(3): 1921-1929.
[11] A S Webb, F Poletti, D J Richardson, et al.. Suspended-core holey fiber for evanescent-field sensing[J]. Opt Eng, 2007, 46(1): 010503.
[12] T Pustelny, M Grabka. Photonic-crystal fibres with suspended core: numerical analyses[J]. Acta Phys Pol A, 2008,114(6-A): 115-120.
[13] T Pustelny, M Grabka. Numerical investigation of the photonic-crystal fibres with suspended core[J]. Acta Phys Pol A, 2009, 116(3): 385-388.
[14] W Q Zhang, V S Afshar, H Ebendorff-Heidepriem, et al.. Record nonlinearity in optical fibre[J]. Electron Lett, 2008, 44(25): 1453-1455.
[15] H Ebendorff-Heidepriem, S C Warren-Smith, T M Monro. Suspended nanowires: fabrication, design and characterization of fibers with nanoscale cores[J]. Opt Express, 2009, 17(4): 2646-2657.
[16] M Liao, C Chaudhari, X Yan, et al.. A suspended core nanofiber with unprecedented large diameter ratio of holey region to core[J]. Opt Express, 2010, 18(9): 9088-9097.
[17] H Ebendorff-Heidepriem, Y Li, T M Monro. Reduced loss in extruded soft glass microstructured fibre[J]. Electron Lett, 2007, 43(24): 1343-1345.
[18] P J Roberts, F Couny, H Sabert, et al.. Loss in solid-core photonic crystal fibers due to interface roughness scattering[J]. Opt Express, 2005, 13(20): 7779-7793.
[19] Y L Hoo, W Jin, C Shi, et al.. Design and modeling of a photonic crystal fiber gas sensor[J]. Appl Opt, 2003, 42(18): 3509-3515.
[20] Y Lu, C Hao, B Wu, et al.. Surface plasmon resonance sensor based on polymer photonic crystal fibers with metal nanolayers[J]. Sensors, 2013, 13(1): 956-965.
[21] M Koshiba, K Saitoh. Structural dependence of effective area and mode field diameter for holey fibers[J]. Opt Express, 2003, 11(15): 1746-1756.
[22] Y K Lizé, E C Mgi, V G Ta′eed, et al.. Microstructured optical fiber photonic wires with subwavelength core diameter[J]. Opt Express, 2004, 12(14): 3209-3217.
[23] L Dong, B K Thomas, L Fu. Highly nonlinear silica suspended core fibers[J]. Opt Express, 2008, 16(21): 16423-16430.
[24] J Y Y Leong, P Petropoulos, J H V Price, et al.. High-nonlinearity dispersion-shifted lead-silicate holey fibers for efficient 1-μm pumped supercontinuum generation[J]. J Lightwave Technol, 2006, 24(1): 183-190.
[25] H Ebendorff-Heidepriem, P Petropoulos, S Asimakis, et al.. Bismuth glass holey fibers with high nonlinearity[J]. Opt Express, 2004, 12(21): 5082-5087.