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

[4] Y LAKHDAR, C TUCK, J BINNER et al. Additive manufacturing of advanced ceramic materials. Progress in Materials Science, 100736(2021).

[5] H L MARCUS, J J BEAMAN, J W BARLOW et al. Solid freeform fabrication-powder processing. American Ceramic Society Bulletin, 1030(1990).

[6] R P CHAUDHARY, C PARAMESWARAN, M IDREES et al. Additive manufacturing of polymer-derived ceramics: materials, technologies, properties and potential applications. Progress in Materials Science, 100969(2022).

[7] P GREIL. Polymer derived engineering ceramics. Advanced Engineering Materials, 339(2000).

[8] A XIA, J YIN, X CHEN et al. Polymer-derived Si-based ceramics: recent developments and perspectives. Crystals, 824(2020).

[10] P COLOMBO, G MERA, R RIEDEL et al. Polymer-derived ceramics: 40 years of research and innovation in advanced ceramics. Journal of the American Ceramic Society, 1805(2010).

[11] S FU, M ZHU, Y ZHU. Organosilicon polymer-derived ceramics: an overview. Journal of Advanced Ceramics, 457(2019).

[12] J W CAO, P WANG, Z Y LIU et al. Research progress on powder-based laser additive manufacturing technology of ceramics. Journal of Inorganic Materials, 241(2022).

[14] Z C ECKEL, C ZHOU, J H MARTIN et al. 3D printing additive manufacturing of polymer-derived ceramics. Science, 58(2016).

[16] W YANG, D YANG, H MEI et al. 3D printing of PDC- SiOC@SiC twins with high permittivity and electromagnetic interference shielding effectiveness. Journal of the European Ceramic Society, 5437(2021).

[17] K HUANG, H ELSAYED, G FRANCHIN et al. 3D printing of polymer-derived SiOC with hierarchical and tunable porosity. Additive Manufacturing, 101549(2020).

[18] X XU, P LI, C GE et al. 3D printing of complex-type SiOC ceramics derived from liquid photosensitive resin. ChemistrySelect, 6862(2019).

[19] H XIONG, L ZHAO, H CHEN et al. 3D SiC containing uniformly dispersed, aligned SiC whiskers: printability, microstructure and mechanical properties. Journal of Alloys and Compounds, 151824(2019).

[20] H XIONG, H CHEN, L ZHAO et al. SiC_w/SiC_preinforced 3D-SiC ceramics using direct ink writing of polycarbosilane-based solution: microstructure, composition and mechanical properties. Journal of the European Ceramic Society, 2648(2019).

[21] K W GYAK, N K VISHWAKARMA, Y H HWANG et al. 3D-printed monolithic SiCN ceramic microreactors from a photocurable preceramic resin for the high temperature ammonia cracking process. Reaction Chemistry & Engineering, 1393(2019).

[22] P JANA, O SANTOLIQUIDO, A ORTONA et al. Polymer- derived SiCN cellular structures from replica of 3D printed lattices. Journal of the American Ceramic Society, 2732(2018).

[23] S AZARNOUSH, F LAUBSCHER, L ZOLI et al. Additive manufacturing of SiCN ceramic matrix for SiC fiber composites by flash pyrolysis of nanoscale polymer films. Journal of the American Ceramic Society, 1855(2016).

[24] O IVANOVA, C WILLIAMS, T CAMPBELL. Additive manufacturing (AM) and nanotechnology: promises and challenges. Rapid Prototyping Journal, 353(2013).

[25] J YANG, R YU, X LI et al. Silicon carbide whiskers reinforced SiOC ceramics through digital light processing 3D printing technology. Ceramics International, 18314(2021).

[26] C HE, C MA, X LI et al. Polymer-derived SiOC ceramic lattice with thick struts prepared by digital light processing. Additive Manufacturing, 101366(2020).

[27] X WANG, F SCHMIDT, D HANAOR et al. Additive manufacturing of ceramics from preceramic polymers: a versatile stereolithographic approach assisted by thiolene click chemistry. Additive Manufacturing, 80(2019).

[28] C MA, C HE, W WANG et al. Metal-doped polymer-derived SiOC composites with inorganic metal salt as the metal source by digital light processing 3D printing. Virtual and Physical Prototyping, 294(2020).

[29] C HE, X LIU, C MA et al. Digital light processing fabrication of mullite component derived from preceramic precursor using photosensitive hydroxysiloxane as the matrix and alumina nanoparticles as the filler. Journal of the European Ceramic Society, 5570(2021).

[30] A KULKARNI, G D SORARU, J M PEARCE. Polymer-derived SiOC replica of material extrusion-based 3-D printed plastics. Additive Manufacturing, 100988(2020).

[31] J XIAO, D LIU, H CHENG et al. Carbon nanotubes as light absorbers in digital light processing three-dimensional printing of SiCN ceramics from preceramic polysilazane. Ceramics International, 19393(2020).

[32] M WANG, C XIE, R HE et al. Polymer-derived silicon nitride ceramics by digital light processing based additive manufacturing. Journal of the American Ceramic Society, 5117(2019).

[34] G PIERIN, C GROTTA, P COLOMBO et al. Direct ink writing of micrometric SiOC ceramic structures using a preceramic polymer. Journal of the European Ceramic Society, 1589(2016).

[35] J SCHMIDT, P COLOMBO. Digital light processing of ceramic components from polysiloxanes. Journal of the European Ceramic Society, 57(2018).

[36] M PELANCONI, P COLOMBO, A ORTONA. Additive manufacturing of silicon carbide by selective laser sintering of PA12 powders and polymer infiltration and pyrolysis. Journal of the European Ceramic Society, 5056(2021).

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

[38] L BRIGO, J E M SCHMIDT, A GANDIN et al. 3D nanofabrication of SiOC ceramic structures. Advanced Science, 1800937(2018).

[39] E ZANCHETTA, M CATTALDO, G FRANCHIN et al. Stereolithography of SiOC ceramic microcomponents. Advanced Materials, 370(2016).

[40] J SCHMIDT, L BRIGO, A GANDIN et al. Multiscale ceramic components from preceramic polymers by hybridization of vat polymerization-based technologies. Additive Manufacturing, 100913(2019).

[41] Y FU, G XU, Z CHEN et al. Multiple metals doped polymer- derived SiOC ceramics for 3D printing. Ceramics International, 11030(2018).

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

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

[44] Z LI, Z CHEN, J LIU et al. Additive manufacturing of lightweight and high-strength polymer-derived SiOC ceramics. Virtual and Physical Prototyping, 163(2020).

[45] Y FU, Z CHEN, G XU et al. Preparation and stereo lithography 3D printing of ultralight and ultrastrong ZrOC porous ceramics. Journal of Alloys and Compounds, 867(2019).

[46] J LIU, S F XIONG, H MEI et al. 3D printing of complex-shaped polymer-derived ceramics with enhanced structural retention. Materials and Manufacturing Processes, 1267(2022).

[47] S F XIONG, J LIU, J W CAO et al. 3D printing of crack-free dense polymer-derived ceramic monoliths and lattice skeletons with improved thickness and mechanical performance. Additive Manufacturing, 102924(2022).

[48] J R TUMBLESTON, D SHIRVANYANTS, N ERMOSHKIN et al. Continuous liquid interface production of 3D objects. Science, 1349(2015).

[49] BEER M P DE, H L VAN DER LAAN, M A COLE et al. Rapid, continuous additive manufacturing by volumetric polymerization inhibition patterning. Science Advances, eaau8(2019).

[50] B KRUNER, C ODENWALD, A TOLOSA et al. Carbide-derived carbon beads with tunable nanopores from continuously produced polysilsesquioxanes for supercapacitor electrodes. Sustainable Energy & Fuels, 1588(2017).

[51] R JANUSZIEWICZ, J R TUMBLESTON, A L QUINTANILLA et al. Layerless fabrication with continuous liquid interface production. Proceedings of the National Academy of Sciences of the United States of America, 11703(2016).

[52] A R JOHNSON, C L CAUDILL, J R TUMBLESTON et al. Single- step fabrication of computationally designed microneedles by continuous liquid interface production. PLOS ONE, e016(2016).

[53] M MAHMOUDI, C WANG, S MORENO et al. Three-dimensional printing of ceramics through "carving" a gel and "filling in" the precursor polymer. ACS Applied Materials & Interfaces, 31984(2020).

[54] M MINARY, M MAHMOUDI. 3D printing polymer-derived ceramics using a thixotropic support bath. American Ceramic Society Bulletin, 32(2021).

[56] M VAEZI, H SEITZ, S YANG. A review on 3D micro-additive manufacturing technologies. International Journal of Advanced Manufacturing Technology, 1721(2013).

[57] W S KIM, R HOUBERTZ, T H LEE et al. Effect of photoinitiator on photopolymerization of inorganic-organic hybrid polymers (ORMOCER (R)). Journal of Polymer Science, 1979(2004).

[58] G KONSTANTINOU, E KAKKAVA, L HAGELUEKEN et al. Additive micro-manufacturing of crack-free PDCs by two-photon polymerization of a single, low-shrinkage preceramic resin. Additive Manufacturing, 101343(2020).

[59] G LIU, Y ZHAO, G WU et al. Origami and 4D printing of elastomer-derived ceramic structures. Science Advances, eaat0(2018).

[60] K W GYAK, N K VISHWAKARMA, Y H HWANG et al. 3D-printed monolithic SiCN ceramic microreactors from a photocurable preceramic resin for the high temperature ammonia cracking process. Reaction Chemistry & Engineering, 1393(2019).

[61] N R BRODNIK, J SCHMIDT, P COLOMBO et al. Analysis of multi-scale mechanical properties of ceramic trusses prepared from preceramic polymers (Revision prepared for additive manufacturing). Additive Manufacturing, 100957(2020).

[62] J W KEMP, N S HMEIDAT, B G COMPTON. Boron nitride- reinforced polysilazane-derived ceramic composites via direct-ink writing. Journal of the American Ceramic Society, 4043(2020).

[63] B ROMAN-MANSO, J J MOYANO, D PEREZ-COLL et al. Polymer-derived ceramic/graphene oxide architected composite with high electrical conductivity and enhanced thermal resistance. Journal of the European Ceramic Society, 2265(2018).

[64] T FRIEDEL, N TRAVITZKY, F NIEBLING et al. Fabrication of polymer derived ceramic parts by selective laser curing. Journal of the European Ceramic Society, 193(2005).

[65] K HUANG, H ELSAYED, G FRANCHIN et al. 3D printing of polymer-derived SiOC with hierarchical and tunable porosity. Additive Manufacturing, 101549(2020).

[66] A ZOCCA, C M GOMES, A STAUDE et al. SiOC ceramics with ordered porosity by 3D-printing of a preceramic polymer. Journal of Materials Research, 2243(2013).

[67] Y R FENG, X GUO, K HUANG et al. Enhanced electromagnetic microwave absorption of SiOC ceramics targeting the integration of structure and function. Journal of the European Ceramic Society, 6393(2021).

[68] T D NGO, A KASHANI, G IMBALZANO et al. Additive manufacturing (3D printing): a review of materials, methods, applications and challenges. Composites Part B-Engineering, 172(2018).

[69] S SINGH, S RAMAKRISHNA, R SINGH. Material issues in additive manufacturing: a review. Journal of Manufacturing Processes, 185(2017).