[1] KARASINSKI P, TYSZKIEWICZ C, DOMANOWSKA A, et al. Low loss, long time stable sol–gel derived silica–titania waveguide films［J］. Materials Letters, 2015, 143: 5-7.

[2] SHAO L Y, CANNING J, WANG T, et al. Viscosity of silica optical fibers characterized using regenerated gratings［J］. Acta Materialia, 2013, 61(16): 6071-6081.

[3] GAO T Q, ZHAO Y, ZHOU G H, et al. Fabrication and characterization of three dimensional woven carbon fiber/silica ceramic matrix composites［J］. Composites Part B: Engineering, 2015, 77: 122-128.

[4] SUN Z M, ZHOU C H, CAO H C, et al. Unified beam splitter of fused silica grating under the second Bragg incidence［J］. Journal of the Optical Society of America A, 2015, 32(11): 1952-1957.

[5] PILATE P, LARDOT V, CAMBIER F, et al. Contribution to the understanding of the high temperature behavior and of the compressive creep behavior of silica refractory materials［J］. Journal of European Ceramic Society, 2015, 35(2): 813-822.

[6] LIAN T W, KONDO A, KOZAWA T, et al. Effect of fumed silica properties on the thermal insulation performance of fibrous compact［J］. Ceramics International, 2015, 41(8): 9966-9971.

[7] VERISSIMO M, GOMES M, Assessment on the use of biodiesel in cold weather: pour point determination using a piezoelectric quartz crystal［J］. Fuel, 2011, 90(90): 2315-2320.

[8] LI K W, WANG Z B, WANG L M, et al. 45° double-drive photoelastic modulation［J］. Journal of the Optical Society of America A, 2016, 33(10): 2041-2046.

[9] KANG Q, SHENG R, LI Y L, et al. Real time monitor electroless plating of Ni–P film on quartz surface by an electrode-separated piezoelectric sensor［J］. Sensors & Actuators B Chemical, 2011, 157(2): 533-539.

[10] LE G D, HELARY G, GINDRE M, et al. Monitoring cell adhesion processes on bioactive polymers with the quartz crystal resonator technique［J］. Biomaterials, 2005, 26(19): 4197-4205

[11] WANG J, WANG Y, HU W K, et al. Huang, parallel finite element analysis of high frequency vibrations of quartz crystal resonators on Linux cluster［J］. Acta Mechanica Solida Sinica, 2008, 21(6): 549-554.

[12] HABIBI N, PASTORINO L, RUGGIERO C, Functionalized biocompatible polyelectrolyte multilayers for drug delivery: In situ investigation of mechanical properties by dissipativequartz crystal microbalance［J］. Materials Science & Enginerring C Materials for Biological Applications, 2014, 35(2): 15-20.

[13] HILLMAN A R, RYDER K S, ZALESKI C J, et al. Application of the combined electrochemical quartz crystal microbalance and probe beam deflection technique in deep eutectic solvents［J］. Electrochimica Acta, 2014, 135(22): 42-51.

[14] VITTORIAS E, KAPPL M, BUTT H J, et al. Studying mechanical microcontacts of fine particles with the quartz crystal microbalance［J］. Powder Technology, 2010, 203(3): 489-502.

[15] XIANG B X, WANG L, JIAO Y, et al. Low-loss optical waveguides preserving photoluminescence features in Pr3+-doped yttrium orthosilicate crystal fabricated by ion implantation［J］. Journal of Lightwave Technology, 2015, 33(11): 2263-2267.

[16] QIAO M, WANG T J, SONG H L, et al. Lattice damage and waveguide properties of medium- and high-energy C3+ ions-irradiated LaAlO3 crystals［J］. Applied Physics B, 2017, 123: 19.

[17] CRESPILLO M L, GRAHAM J T, ZHANG Y, et al. In-situ luminescence monitoring of ion-induced damage evolution in SiO2 and Al2O3［J］. Journal of Luminescence, 2016, 172: 208-218.

[18] PLAKSIN O A, TAKEDA Y, KONO K, et al. Optical effects in silica glass during implantation of 60 keV Cu- ions［J］. Applied Surface Science, 2005, 244(1): 79-83.

[19] Ramírez-Espinoza C, Salazar D, Rangel-Rojo R, et al. Design of step-index optical waveguides by ion implantation［J］. Journal of Lightwave Technology, 2015, 33(14): 3052-3059.

[20] ZIEGLER J F. "Computer code", SRIM2013［EB/OL］. ［2016-12-16］. http: //www.srim.org.

[21] CHANDLER P J, LAMA F L, A new approach to the determination of planar waveguide profiles by means of a non-stationary mode index calculation［J］. Journal of Modern Optics, 1986, 33(2): 127-143.

[22] WANG T J, ZHOU Y F, YU X F, et al. Optical waveguide properties of Ca0.4Ba0.6Nb2O6, crystal formed by oxygen ion irradiation［J］. Nuclear Instruments & Methods in Physics Research, 2015, 354: 187-191.

[23] TAN Y, CHEN F, WANG L, et al. Carbon ion-implanted optical waveguides in Nd: YLiF4 crystal: Refractive index profiles and thermal stability［J］. Nuclear Instruments and Methods in Physics Research B, 2007, 260(2): 567-570.

[24] BENTINI G G, BIANCONI M, CHIARINI M, et al. Effect of low dose high energy O3+ implantationon refractive index and linear electro-optic properties in X-cut LiNbO3: planaroptical waveguide formation and characterization［J］. Journal of Applied Physics, 2002, 92(11): 6477-6483.

[25] LIU X H, ZHAO J H, ZHANG S M, et al. Damage behaviors in Nd: YVO4 by multi-energy proton implantation［J］. Nuclear Instruments & Methods in Physics Research, 2012, 286(9): 213–217.

[26] MANZANO-Santamaría J, OLIVARES J, RIVERA A, et al. Electronic damage in quartz (c-SiO2) by MeV ion irradiations: Potentiality for optical waveguiding applications［J］. Nuclear Instruments & Methods in Physics Research, 2012, 272(3): 271-274.

[27] JIANG Y, WANG K M, WANG X L, et al. Model of refractive-index changes in lithium niobate waveguides fabricated by ion implantation［J］. Physical Review B, 2007, 75: 195101.