[2] Lipovskii A, Zhurikhina V, Tagantsev D. 2D-structuring of glasses via thermal poling: a short review[J]. International Journal of Applied Glass Science, 9, 24-28(2018).
[3] Tian F J, Yuan L B, Liu Z H et al. An elliptical-core hollow fiber with high second-order nonlinearity[J]. Acta Optica Sinica, 32, 0106001(2012).
[4] Myers R A, Mukherjee N, Brueck S R. Large second-order nonlinearity in poled fused silica[J]. Optics Letters, 16, 1732-1734(1991).
[5] Chen Z, Liao Y B, Hu Y M et al. Electro-optic phase modulator with thermally poled PANDA fiber[J]. Chinese Journal of Lasers, 28, 1003-1006(2001).
[6] Chen Z, Liao Y B, Zhang G L et al. In situ investigations of thermal poling process of optical fibers[J]. Acta Optica Sinica, 25, 169-173(2005).
[7] Guignard M, Nazabal V, Smektala F et al. Chalcogenide glasses based on germanium disulfide for second harmonic generation[J]. Advanced Functional Materials, 17, 3284-3294(2007).
[8] Delestre A, Lahaye M, Fargin E et al. Towards second harmonic generation micro-patterning of glass surface. [C]∥Bragg Gratings, Photosensitivity, and Poling in Glass Waveguides 2010, June 21-24, 2010, Karlsruhe, Germany. Washington, DC: OSA, JThA31(2010).
[9] Lipovskii A A, Kuittinen M, Karvinen P et al. Electric field imprinting of sub-micron patterns in glass-metal nanocomposites[J]. Nanotechnology, 19, 415304(2008).
[11] Lipovskii A A, Rusan V V, Tagantsev D K. Imprinting phase/amplitude patterns in glasses with thermal poling[J]. Solid State Ionics, 181, 849-855(2010).
[12] Yang G, Cao J, Qi Y H et al. Imprinting gradient refractive index micro-structure in GeS2-Ga2S3-KCl glass for broadband diffraction grating[J]. Optical Materials, 101, 109766(2020).
[13] Yang G, Qi Y H, Cao J et al. Ultralow voltage imprinting in GeS2-Ga2S3-AgI glasses for visible to middle-infrared diffraction gratings[J]. Ceramics International, 46, 9030-9039(2020).
[14] Sokolov K, Melehin V, Petrov M et al. Spatially periodical poling of silica glass[J]. Journal of Applied Physics, 111, 104307(2012).
[15] Lepicard A, Adamietz F, Rodriguez V et al. Demonstration of dimensional control and stabilization of second harmonic electro-optical response in chalcogenide glasses[J]. Optical Materials Express, 8, 1613-1624(2018).
[16] Yang G, Dussauze M, Rodriguez V et al. Large scale micro-structured optical second harmonic generation response imprinted on glass surface by thermal poling[J]. Journal of Applied Physics, 118, 043105(2015).
[17] Dussauze M, Rodriguez V, Adamietz F et al. Accurate second harmonic generation microimprinting in glassy oxide materials[J]. Advanced Optical Materials, 4, 929-935(2016).
[18] He X Y, Hu D M, Yang G et al. Microstructured SHG patterns on Sm2O3-doped borophosphate niobium glasses by laser-induced thermal poling[J]. Ceramics International, 47, 10123-10129(2021).
[21] Cremoux T, Dussauze M, Fargin E et al. Trapped molecular and ionic species in poled borosilicate glasses: toward a rationalized description of thermal poling in glasses[J]. The Journal of Physical Chemistry C, 118, 3716-3723(2014).
[22] Dussauze M, Rodriguez V, Lipovskii A et al. How does thermal poling affect the structure of soda-lime glass?[J]. The Journal of Physical Chemistry C, 114, 12754-12759(2010).
[23] Skuja L, Güttler B. Detection of interstitial oxygen molecules in SiO2 glass by a direct photoexcitation of the infrared luminescence of singlet O2[J]. Physical Review Letters, 77, 2093-2096(1996).
[24] Boizot B, Petite G, Ghaleb D et al. Raman study of β-irradiated glasses[J]. Journal of Non-Crystalline Solids, 243, 268-272(1999).