[1] [1] TYUGANOVA M A,ZUBKOVA N S,BUTYLKINA N G. Polymeric fibre materials with low combustibility： a review［J］. Fibre Chemistry,1994,26(5): 294-305.

[2] [2] XUE W J,YI J,XIE Z P,et al. Enhanced fracture toughness of silicon nitride ceramics at cryogenic temperatures［J］. Scripta Materialia,2012,66(11): 891-894.

[3] [3] KRSTIC Z,KRSTIC V D. Silicon nitride: the engineering material of the future［J］. Journal of Materials Science,2012,47(2): 535-552.

[4] [4] ZHOU Y,HYUGA H,KUSANO D,et al. Development of high-thermal-conductivity silicon nitride ceramics［J］. Journal of Asian Ceramic Societies,2015,3(3): 221-229.

[5] [5] BOCANEGRA-BERNAL M H,MATOVIC B. Mechanical properties of silicon nitride-based ceramics and its use in structural applications at high temperatures［J］. Materials Science and Engineering: A,2010,527(6): 1314-1338.

[6] [6] YANG Y,SONG X,LI X J,et al. Recent progress in biomimetic additive manufacturing technology: from materials to functional structures［J］. Advanced Materials,2018,30(36): 1706539.

[7] [7] CHEN Z W,LI Z Y,LI J J,et al. 3D printing of ceramics: a review［J］. Journal of the European Ceramic Society,2019,39(4): 661-687.

[8] [8] ABOULIATIM Y,CHARTIER T,ABELARD P,et al. Optical characterization of stereolithography alumina suspensions using the Kubelka-Munk model［J］. Journal of the European Ceramic Society,2009,29(5): 919-924.

[9] [9] ZOCCA A,COLOMBO P,GOMES C M,et al. Additive manufacturing of ceramics: issues,potentialities,and opportunities［J］. Journal of the American Ceramic Society,2015,98(7): 1983-2001.

[10] [10] WANG F,LI L,SONG T,et al. Study on preparation and sintering of porous silicon nitride ceramics based on fused deposition technology［J］. Advanced Ceramics,2023,44(supplement 1): 461-472 (in Chinese).

[11] [11] DONG X J,WU J Q,YU H L,et al. Additive manufacturing of silicon nitride ceramics: a review of advances and perspectives［J］. International Journal of Applied Ceramic Technology,2022,19(6): 2929-2949.

[12] [12] ZANCHETTA E,CATTALDO M,FRANCHIN G,et al. Stereolithography of SiOC ceramic microcomponents［J］. Advanced Materials,2016,28(2): 370-376.

[13] [13] ZHANG K Q,HE R J,XIE C,et al. Photosensitive ZrO2 suspensions for stereolithography［J］. Ceramics International,2019,45(9): 12189-12195.

[14] [14] SUN J X,BINNER J,BAI J M. Effect of surface treatment on the dispersion of nano zirconia particles in non-aqueous suspensions for stereolithography［J］. Journal of the European Ceramic Society,2019,39(4): 1660-1667.

[15] [15] SUN J X,BINNER J,BAI J M. 3D printing of zirconia via digital light processing: optimization of slurry and debinding process［J］. Journal of the European Ceramic Society,2020,40(15): 5837-5844.

[16] [16] ZHANG K Q,MENG Q Y,ZHANG X Q,et al. Roles of solid loading in stereolithography additive manufacturing of ZrO2 ceramic［J］. International Journal of Refractory Metals and Hard Materials,2021,99: 105604.

[17] [17] HAN Z Q,LIU S H,QIU K,et al. The enhanced ZrO2 produced by DLP via a reliable plasticizer and its dental application［J］. Journal of the Mechanical Behavior of Biomedical Materials,2023,141: 105751.

[18] [18] WANG Y,ZHOU Q X,HAN Z Q,et al. Towards high strengthening efficiency of equiaxed and platelet-shaped alumina reinforced zirconia ceramics with textured microstructure using DLP-based stereolithography［J］. Ceramics International,2024,50(1): 2467-2478.

[19] [19] XING H Y,ZOU B,LAI Q G,et al. Preparation and characterization of UV curable Al2O3 suspensions applying for stereolithography 3D printing ceramic microcomponent［J］. Powder Technology,2018,338: 153-161.

[20] [20] ZHANG S,SHA N,ZHAO Z. Surface modification of α-Al2O3 with dicarboxylic acids for the preparation of UV-curable ceramic suspensions［J］. Journal of the European Ceramic Society,2017,37(4): 1607-1616.

[21] [21] GU Y,DUAN W Y,WANG T C,et al. Additive manufacturing of Al2O3 ceramic core with applicable microstructure and mechanical properties via digital light processing of high solid loading slurry［J］. Ceramics International,2023,49(15): 25216-25224.

[22] [22] GU Q C,SUN L,JI X Y,et al. High-performance and high-precision Al2O3 architectures enabled by high-solid-loading,graphene-containing slurries for top-down DLP 3D printing［J］. Journal of the European Ceramic Society,2023,43(1): 130-142.

[23] [23] XU X H,ZHOU S X,WU J F,et al. Inter-particle interactions of alumina powders in UV-curable suspensions for DLP stereolithography and its effect on rheology,solid loading,and self-leveling behavior［J］. Journal of the European Ceramic Society,2021,41(4): 2763-2774.

[24] [24] WANG Y Y,WANG Z Y,LIU S H,et al. Additive manufacturing of silica ceramics from aqueous acrylamide based suspension［J］. Ceramics International,2019,45(17): 21328-21332.

[25] [25] KCS L,TEGZE B,ALBERT E,et al. Ammonia-vapour-induced two-layer transformation of mesoporous silica coatings on various substrates［J］. Vacuum,2021,192: 110415.

[26] [26] BAE C J,KIM D,HALLORAN J W. Mechanical and kinetic studies on the refractory fused silica of integrally cored ceramic mold fabricated by additive manufacturing［J］. Journal of the European Ceramic Society,2019,39(2/3): 618-623.

[27] [27] LIU Y,CHEN Z W. Research progress in photopolymerization-based 3D printing technology of ceramics［J］. Journal of Materials Engineering,2020,48(9): 1-12 (in Chinese).

[28] [28] HINCZEWSKI C,CORBEL S,CHARTIER T. Ceramic suspensions suitable for stereolithography［J］. Journal of the European Ceramic Society,1998,18(6): 583-590.

[29] [29] GU Y,WANG G,DUAN W Y,et al. Application and prospect of photopolymerization technologies for ceramics［J］. Journal of the Chinese Ceramic Society,2021,49(5): 867-877 (in Chinese).

[30] [30] ZAKERI S,VIPPOLA M,LEVNEN E. A comprehensive review of the photopolymerization of ceramic resins used in stereolithography［J］. Additive Manufacturing,2020,35: 101177.

[31] [31] YANG Y,GUO X T,TANG J,et al. Research progress and prospects of non-oxide ceramic in stereolithography additive manufacturing［J］. Journal of Inorganic Materials,2022,37(3): 267-277 (in Chinese).

[32] [32] HAN Z Q,LI L,LIU S H,et al. Research on rheological properties of stereolithography ZrO2 ceramic slurry［J］. Bulletin of the Chinese Ceramic Society,2021,40(6): 1965-1971 (in Chinese).

[33] [33] SUBBANNA M,KAPUR P C,PRADIP. Role of powder size,packing,solid loading and dispersion in colloidal processing of ceramics［J］. Ceramics International,2002,28(4): 401-405.

[34] [34] GRIFFITH M L,HALLORAN J W. Freeform fabrication of ceramics via stereolithography［J］. Journal of the American Ceramic Society,1996,79(10): 2601-2608.

[35] [35] LIU S,MO L N,BI G Y,et al. DLP 3D printing porous β-tricalcium phosphate scaffold by the use of acrylate/ceramic composite slurry［J］. Ceramics International,2021,47(15): 21108-21116.

[36] [36] LIN L F,WU H D,XU Y R,et al. Fabrication of dense aluminum nitride ceramics via digital light processing-based stereolithography［J］. Materials Chemistry and Physics,2020,249: 122969.

[37] [37] LIU Y,ZHAN L N,HE Y,et al. Stereolithographical fabrication of dense Si3N4 ceramics by slurry optimization and pressure sintering［J］. Ceramics International,2020,46(2): 2063-2071.

[38] [38] HALLORAN J W. Ceramic stereolithography: additive manufacturing for ceramics by photopolymerization［J］. Annual Review of Materials Research,2016,46: 19-40.

[39] [39] MU Y H,CHEN J W,AN X L,et al. Effect of synergism of solid loading and sintering temperature on microstructural evolution and mechanical properties of 60vol% high solid loading ceramic core obtained through stereolithography 3D printing［J］. Journal of the European Ceramic Society,2023,43(2): 661-675.

[40] [40] GRIFFITH M L,HALLORAN J W. Scattering of ultraviolet radiation in turbid suspensions［J］. Journal of Applied Physics,1997,81(6): 2538-2546.

[41] [41] LI X B,ZHANG J X,DUAN Y S,et al. Rheology and curability characterization of photosensitive slurries for 3D printing of Si3N4 ceramics［J］. Applied Sciences,2020,10(18): 6438.

[42] [42] HUANG R J,JIANG Q G,WU H D,et al. Fabrication of complex shaped ceramic parts with surface-oxidized Si3N4 powder via digital light processing based stereolithography method［J］. Ceramics International,2019,45(4): 5158-5162.

[43] [43] LI Y H,HUANG S W,WANG S L,et al. Research on the effects of surface modification of ceramic powder on cure performance during digital light processing (DLP)［J］. Ceramics International,2022,48(3): 3652-3658.

[44] [44] LIU Y,CHENG L J,LI H,et al. Formation mechanism of stereolithography of Si3N4 slurry using silane coupling agent as modifier and dispersant［J］. Ceramics International,2020,46(10): 14583-14590.

[45] [45] LI M,HUANG H L,WU J M,et al. Preparation and properties of Si3N4 ceramics via digital light processing using Si3N4 powder coated with Al2O3-Y2O3 sintering additives［J］. Additive Manufacturing,2022,53: 102713.

[46] [46] LIU Y,ZHAN L N,WEN L,et al. Effects of particle size and color on photocuring performance of Si3N4 ceramic slurry by stereolithography［J］. Journal of the European Ceramic Society,2021,41(4): 2386-2394.

[47] [47] HUANG S W,LI Y H,YANG P,et al. Cure behaviour and mechanical properties of Si3N4 ceramics with bimodal particle size distribution prepared using digital light processing［J］. Ceramics International,2023,49(8): 12166-12172.

[48] [48] LIN L F,WU H D,HUANG Z Q,et al. Effect of monomers with different functionalities on stability,rheology,and curing behavior of ceramic suspensions［J］. Materials Chemistry and Physics,2022,275: 125243.

[49] [49] ZOU W J,YANG P,LIN L F,et al. Improving cure performance of Si3N4 suspension with a high refractive index resin for stereolithography-based additive manufacturing［J］. Ceramics International,2022,48(9): 12569-12577.

[50] [50] CAO C R,WANG C,ZHAO Z. Optimization of curing behavior of Si3N4 UV resin for photopolymerization 3D printing［J］. IOP Conference Series: Materials Science and Engineering,2019,678(1): 012013.

[51] [51] SHEN M H,FU R L,LIU H B,et al. Photosensitive Si3N4 slurry with combined benefits of low viscosity and large cured depth for digital light processing 3D printing［J］. Journal of the European Ceramic Society,2023,43(3): 881-888.

[52] [52] CHEN R F,DUAN W Y,WANG G,et al. Preparation of broadband transparent Si3N4-SiO2 ceramics by digital light processing (DLP) 3D printing technology［J］. Journal of the European Ceramic Society,2021,41(11): 5495-5504.

[53] [53] TIAN C,WU J M,WU Y R,et al. Effect of polystyrene addition on properties of porous Si3N4 ceramics fabricated by digital light processing［J］. Ceramics International,2023,49(16): 27040-27049.

[54] [54] WU Y R,TIAN C,WU J M,et al. Influence of the content of polymethyl methacrylate on the properties of porous Si3N4 ceramics fabricated by digital light processing［J］. Ceramics International,2023,49(19): 31228-31235.

[55] [55] WU Y R,TIAN C,WU J M,et al. Influence of the ratio of sintering aids on the properties of porous Si3N4 ceramics fabricated by digital light processing［J］. Ceramics International,2023,49(20): 33004-33010.