[1] |
BOCANEGRA-BERNAL M H, MATOVIC B. Mechanical properties of silicon nitride-based ceramics and its use in structural applications at high temperatures. Materials Science and Engineering: A, 2010, 527(6): 1314-1338.
DOI
URL
|
[2] |
DANTE R C, KAJDAS C K. A review and a fundamental theory of silicon nitride tribochemistry. Wear, 2012, 288(3): 27-38.
DOI
URL
|
[3] |
SUN Y G, HE S L, LIU R A, et al. Preparation and application of silicon nitride ceramics. China Ceramic Industry, 2016, 23(5): 31-34.
|
[4] |
RILEY F L. Silicon nitride and related materials. Journal of the American Ceramic Society, 2000, 83(2): 245-265.
DOI
URL
|
[5] |
KLEMM H. Silicon nitride for high-temperature applications. Journal of the American Ceramic Society, 2010, 93(6): 1501-1522.
DOI
URL
|
[6] |
KRSTIC Z, KRSTIC V D. Silicon nitride: the engineering material of the future. Journal of Materials Science, 2012, 47(2): 535-552.
DOI
URL
|
[7] |
WANG B M. State of the art of advanced ceramic material. Progress in Chemistry, 2000, 12(3): 357-359.
|
[8] |
NISHIMURA T, MITOMO M, SUEMATSU H. High temperature strength of silicon nitride ceramics with ytterbium silicon oxynitride. Journal of Materials Research, 1997, 12(1): 203-209.
DOI
URL
|
[9] |
CHEN A N, WU J M, HAN L X, et al. Preparation of Si3N4 foams by DCC method via dispersant reaction combined with protein-gelling. Journal of Alloys and Compounds, 2018, 745(1): 262-270.
DOI
URL
|
[10] |
XIE G R, ZHANG X G, CEN X D. Study and application of silicon nitride ceramic cutting tool. Tool Engineering, 2007, 41(2): 78-80.
|
[11] |
PYZIK A J, BEAMAN D R. Microstructure and properties of self-reinforced silicon nitride. Journal of the American Ceramic Society, 1993, 76(11): 2737-2744.
DOI
URL
|
[12] |
NEUMANN A, RESKE T, HELD M, et al. Comparative investigation of the biocompatibility of various silicon nitride ceramic qualities in vitro. Journal of Materials Science: Materials in Medicine, 2004, 15(10): 1135-1140.
DOI
URL
|
[13] |
ORTH J, LUDWIG M, PIENING W, et al. Biocompatibility of Silicon Carbide and Silicon Nitride Ceramics. Results of an Animal Experiment. Bioceramics and the Human Body. Berlin: Springer, 1992, 28(12): 372-377.
|
[14] |
KANDI K K, THALLAPALLI N, CHILAKALAPALLI S P R. Development of silicon nitride-based ceramic radomes-a review. International Journal of Applied Ceramic Technology, 2015, 12(5): 909-920.
DOI
URL
|
[15] |
WU W J, LIU J, ZHANG J, et al. Preparation and application status of porous Si3N4 ceramic. China Ceramics, 2016, 52(7): 10-13.
|
[16] |
HE J H, WU J M, CHEN A N, et al. Ceramic materials for additive manufacturing and their forming technologies. Materials China, 2020, 39(5): 337-348.
|
[17] |
CHEN Z W, LI Z Y, LI J J, et al. 3D printing of ceramics: a review. Journal of European Ceramic Society, 2019, 39(4): 661-687.
DOI
URL
|
[18] |
LIU S S, LI M, WU J M, et al. Preparation of high-porosity Al2O3 ceramic foams via selective laser sintering of Al2O3 poly-hollow microspheres. Ceramics International, 2020, 46(4): 4240-4247.
DOI
URL
|
[19] |
WONG K V, HERNANDEZ A. A review of additive manufacturing. ISRN Mechanical Engineering, 2012, 34(15): 30-38.
|
[20] |
CHEN F, ZHU H, WU J M, et al. Preparation and biological evaluation of ZrO2 all-ceramic teeth by DLP technology. Ceramics International, 2020, 46(8): 11268-11274.
DOI
URL
|
[21] |
DMITRII A K, PETR S S, ANASTASIYA D E, et al. Rheological and curing behavior of acrylate-based suspensions for the DLP 3D printing of complex zirconia parts. Materials, 2018, 11(12): 2350-2362
DOI
URL
|
[22] |
LI S, DUAN W, ZHAO T, et al. The fabrication of SiBCN ceramic components from preceramic polymers by digital light processing (DLP) 3D printing technology. Journal of the European Ceramic Society, 2018, 38(14): 4597-4603.
DOI
URL
|
[23] |
WU J M, YANG Y Q, WANG C, et al. Photopolymerization technologies for ceramics and their applications. Journal of Mechanical Engineering, 2020, 56(19): 221-238.
|
[24] |
SHUAI X, ZENG Y, LI P, et al. Fabrication of fine and complex lattice structure Al2O3 ceramic by digital light processing 3D printing technology. Journal of Materials Science, 2020, 55(3): 6771-6782.
DOI
URL
|
[25] |
HE R, LIU W, WU Z, et al. Fabrication of complex-shaped zirconia ceramic parts via a DLP-stereolithography-based 3D printing method. Ceramics International, 2018, 44(3): 3412-3416.
DOI
URL
|
[26] |
HUA S B, ZHU H, WU J M, et al. Performance of lattice structure scaffold prepared via digital light processing manufacture by DLP technology. Journal of Chinese Ceramic Society, 2021, 49(4): 608-617.
|
[27] |
GRIFFITH M L, HALLORAN J W. Ultraviolet Curing of Highly Loaded Ceramic Suspensions for Stereolithography of Ceramics. Proc. Solid Freeform Fabr. Symp., 1994: 396-403.
|
[28] |
WU X Q, XU C J, ZHANG Z M. Preparation and optimization of Si3N4 ceramic slurry for low-cast LCD mask stereolithography. Ceramics International, 2021, 47(7): 9400-9408.
DOI
URL
|
[29] |
DING G J, HE R J, ZHANG K Q, et al. Stereolithography-based additive manufacturing of gray-colored SiC ceramic green body. Journal of the American Ceramic Society, 2019, 102(12): 7198-7209.
DOI
URL
|
[30] |
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. Ceramics International, 2019, 45(4): 5158-5162.
DOI
URL
|