[1] A CAMERUCCI M, G URRETAVIZCAYA, S CASTRO M et al. Electrical properties and thermal expansion of cordierite and cordierite- mullite materials. Journal of the European Ceramic Society, 21, 2917-2923(2001).

[2] S LAMARA, D REDAOUI, F SAHNOUNE et al. Microstructure, thermal expansion, hardness and thermodynamic parameters of cordierite materials synthesized from Algerian natural clay minerals and magnesia. Boletín de la Sociedad Española de Cerámica y Vidrio, 60, 291-306(2020).

[3] S SITTIAKKARANON. Thermal shock resistance of mullite- cordierite ceramics from kaolin, talc and alumina raw materials. Materials Today: Proceedings, 17, 1864-1871(2019).

[4] Z CHEN, C LIU, J LI et al. Mechanical properties and microstructures of 3D printed bulk cordierite parts. Ceramics International, 45, 19257-19267(2019).

[5] H GÖKÇE, D AĞAOĞULLARI, L ÖVEÇOĞLU M et al. Characterization of microstructural and thermal properties of steatite/ cordierite ceramics prepared by using natural raw materials. Journal of the European Ceramic Society, 31, 2741-2747(2011).

[6] P AVILA, M MONTES, E MIRÓ E. Monolithic reactors for environmental applications: a review on preparation technologies. Chemical Engineering Journal, 109, 11-36(2005).

[7] N DAS R, D MADHUSOODANA C, K OKADA. Rheological studies on cordierite honeycomb extrusion. Journal of the European Ceramic Society, 22, 2893-2900(2002).

[8] Q LIANG, D LI, G YANG. Rapid fabrication of diamond-structured ceramic photonic crystals with graded dielectric constant and its controllable stop band properties. Ceramics International, 39, 153-157(2013).

[9] W MELCHELS F P, J FEIJEN, W GRIJPMA D. A review on stereolithography and its applications in biomedical engineering. Biomaterials, 31, 6121-6130(2010).

[10] W ZHOU, D LI, Z CHEN. Direct fabrication of an integral ceramic mould by stereolithography. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 224, 237-243(2010).

[11] A ZOCCA, P COLOMBO, M GOMES C et al. Additive manufacturing of ceramics: issues, potentialities, and opportunities. Journal of the American Ceramic Society, 98, 1983-2001(2015).

[12] Z CHEN, Z LI, J LI et al. 3D printing of ceramics: a review. Journal of the European Ceramics Society, 39, 661-687(2019).

[13] Z CHEN, D LI, W ZHOU. Process parameters appraisal of fabricating ceramic parts based on stereolithography using the Taguchi method. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 226, 1249-1258(2012).

[14] Y LIU, Z CHEN, J LI et al. 3D printing of ceramic cellular structures for potential nuclear fusion application. Additive Manufacturing, 35, 101348(2020).

[15] A RASAKI S, D XIONG, S XIONG et al. Photopolymerization- based additive manufacturing of ceramics: a systematic review. Journal of Advanced Ceramics, 10, 442-471(2021).

[16] C LIU, F XU, Y LIU et al. High mass loading ultrathick porous Li₄Ti₅O₁₂ electrodes with improved areal capacity fabricated via low temperature direct writing. Electrochimica Acta, 314, 81-88(2019).

[17] Z WU, Z HUAN, Y ZHU et al. 3D printing and characterization of microsphere hydroxyapatite scaffolds. Journal of Inorganic Materials, 36, 601-607(2021).

[18] Z CHEN, N BRANDON. Inkjet printing and nanoindentation of porous alumina multilayers. Ceramics International, 42, 8316-8324(2016).

[19] Z CHEN, J OUYANG, W LIANG et al. Development and characterizations of novel aqueous-based LSCF suspensions for inkjet printing. Ceramics International, 44, 13381-13388(2018).

[20] L ZHANG, X YANG, X XU et al. 3D printed zirconia ceramics via fused deposit modeling and its mechanical properties. Journal of Inorganic Materials, 36, 436-442(2021).

[21] S LIU, M LI, J WU et al. Preparation of high-porosity Al₂O₃ ceramic foams via selective laser sintering of Al₂O₃ poly-hollow microspheres. Ceramics International, 46, 4240-4247(2020).

[22] L FERRAGE, G BERTRAND, P LENORMAND. Dense yttria- stabilized zirconia obtained by direct selective laser sintering. Additive Manufacturing, 21, 472-478(2018).

[23] T MINASYAN, L LIU, M AGHAYAN et al. A novel approach to fabricate Si₃N₄ by selective laser melting. Ceramics International, 44, 13689-13694(2018).

[24] Z CHEN, J LI, C LIU et al. Preparation of high solid loading and low viscosity ceramic slurries for photopolymerization-based 3D printing. Ceramics International, 45, 11549-11557(2019).

[25] X SHUAI, Y ZENG, P LI et al. Fabrication of fine and complex lattice structure Al₂O₃ ceramic by digital light processing 3D printing technology. Journal of Materials Science, 55, 6771-6782(2020).

[26] H LI, L SONG, J SUN et al. Stereolithography-fabricated zirconia dental prostheses: concerns based on clinical requirements. Journal of Advances in Applied Ceramics, 119, 236-243(2020).

[27] C FENG, C ZHANG, R HE et al. Additive manufacturing of hydroxyapatite bioceramic scaffolds: dispersion, digital light processing, sintering, mechanical properties, and biocompatibility. Journal of Advanced Ceramics, 9, 360-373(2020).

[28] R HE, G DING, K ZHANG et al. Fabrication of SiC ceramic architectures using stereolithography combined with precursor infiltration and pyrolysis. Ceramics International, 45, 14006-14014(2019).

[29] C ZHANG, Z LUO, C LIU et al. Dimensional retention of photocured ceramic units during 3D printing and sintering processes. Ceramics International, 47, 11097-11108(2021).

[30] Z CHEN, C LIU, J LI et al. Mechanical properties and microstructures of 3D printed bulk cordierite parts. Ceramics International, 45, 19257-19267(2019).