[1] W CHEN Z, Y LI Z, J LI J et al. 3D printing of ceramics: a review. Journal of the European Ceramic Society, 39, 661-687(2019).
[2] L WANG J, L LI F, Q HU B. Present situation and development of fine alumina in China. Ceramic, 2021, 12-14.
[3] B ZHU Z, J GUO Z, Y LIU. Development and application of alumina ceramics. Ceramic, 2003, 5-8.
[4] M SABAH A, H M A AZMAH, C N A JAAFAR et al. Effect of Cu metal of nanoscale particle size on the porosity and mechanical properties of porous alumina ceramics using yeast as a pore agent. Research Journal of Applied Sciences, Engineering and Technology, 14, 187-195(2017).
[5] R MEZA L, S DAS, R GREER J. Strong, lightweight, and recoverable three-dimensional ceramic nanolattices. Science, 345, 1322-1326(2014).
[6] Q ZHANG K, J HE R, J DING G et al. Effects of fine grains and sintering additives on stereolithography additive manufactured Al2O3 ceramic. Ceramics International, 47, 2303-2310(2021).
[7] M BENGISU, 115-126(2013).
[8] S PINARGOTE N W, A SMIRNOV, N PERETYAGIN et al. Direct ink writing technology (3D printing) of graphene-based ceramic nanocomposites: a review. Nanomaterials, 10, 1300(2020).
[9] C JI H, J ZHANG X, C PEI W et al. Research progress of ceramic 3D printing technology and materials. Material Engineering, 46, 19-28(2018).
[10] D LIANG, J HE R, N FANG D. Research status of manufacturing technology of ceramic materials and structural additives. Advanced Ceramics, 38, 231-247(2017).
[11] J YANG W, J AN, K CHUA C et al. Acoustic absorptions of multifunctional polymeric cellular structures based on triply periodic minimal surfaces fabricated by stereolithography. Virtual and Physical Prototyping, 15, 242-249(2020).
[12] F AZARMI, A AMIRI. Microstructural evolution during fabrication of alumina via laser stereolithography technique. Ceramics International, 45, 271-278(2019).
[13] H WEI Y, Y ZHAO D, L CAO Q et al. Stereolithography-based additive manufacturing of high-performance osteoinductive calcium phosphate ceramics by a digital light- processing system. ACS Biomaterials Science & Engineering, 6, 1787-1797(2020).
[14] H LEE Y, W LEE J, Y YANG S et al. Dual-scale porous biphasic calcium phosphate gyroid scaffolds using ceramic suspensions containing polymer microsphere porogen for digital light processing. Ceramics International, 47, 11285-11293(2021).
[15] H YVES-CHRISTIAN, W JAN, M WILHELM et al. Net shaped high performance oxide ceramic parts by selective laser melting. Physics Procedia, 5, 587-594(2010).
[16] K LIU, J SUN H, L TAN Y et al. Additive manufacturing of traditional ceramic powder via selective laser sintering with cold isostatic pressing. The International Journal of Advanced Manufacturing Technology, 90, 945-952(2017).
[17] P KRUTH J, P MERCELIS, J van VAERENBERGH et al. Binding mechanisms in selective laser sintering and selective laser melting. Rapid Prototyping Journal, 11, 26-36(2005).
[18] F CHEN, H ZHU, M WU J et al. Preparation and biological evaluation of ZrO2 all-ceramic teeth by DLP technology. Ceramics International, 46, 11268-11274(2020).
[19] K ENNETI R, J PARK S, M GERMAN R et al. Review: thermal debinding process in particulate materials processing. Materials and Manufacturing Processes, 27, 103-118(2012).
[20] Y XING H, B ZUO, S LI S et al. Study on surface quality, precision and mechanical properties of 3D printed ZrO2 ceramic components by laser scanning stereolithography. Ceramics International, 43, 16340-16347(2018).
[21] Q LIAN, Q WU X, C LI D et al. Accurate printing of a zirconia molar crown bridge using three-part auxiliary supports and ceramic mask projection stereolithography. Ceramics International, 45, 18814-18822(2019).
[22] K WANG, B QIU M, J CHEN et al. Study on defect-free debinding green body of ceramic formed by DLP technology. Ceramics International, 46, 2438-244(2020).