AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
PDF (40.8 MB)
Collect
Submit Manuscript AI Chat Paper
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Review | Open Access

Progress and challenges towards additive manufacturing of SiC ceramic

Rujie HEa( )Niping ZHOUa,bKeqiang ZHANGa,bXueqin ZHANGa,bLu ZHANGa,bWenqing WANGa,bDaining FANGa
Institute of Advanced Structure Technology, Beijing Institute of Technology, Beijing 100081, China
School of Materials Science and Engineering, Beijing Institute of Technology, Beijing 100081, China
Show Author Information

Abstract

Silicon carbide (SiC) ceramic and related materials are widely used in various military and engineering fields. The emergence of additive manufacturing (AM) technologies provides a new approach for the fabrication of SiC ceramic products. This article systematically reviews the additive manufacturing technologies of SiC ceramic developed in recent years, including Indirect Additive Manufacturing (Indirect AM) and Direct Additive Manufacturing (Direct AM) technologies. This review also summarizes the key scientific and technological challenges for the additive manufacturing of SiC ceramic, and also forecasts its possible future opportunities. This paper aims to provide a helpful guidance for the additive manufacturing of SiC ceramic and other structural ceramics.

References

[1]
Liu GW, Zhang XZ, Yang J, et al. Recent advances in joining of SiC-based materials (monolithic SiC and SiCf/SiC composites): Joining processes, joint strength, and interfacial behavior. J Adv Ceram 2019, 8: 19-38.
[2]
Chen XW, Cheng GF, Zhang JM, et al. Residual stress variation in SiCf/SiC composite during heat treatment and its effects on mechanical behavior. J Adv Ceram 2020, 9: 567-575.
[3]
Liu JW, Zhou XB, Tatarko P, et al. Fabrication, microstructure, and properties of SiC/Al4SiC4 multiphase ceramics via an in situ formed liquid phase sintering. J Adv Ceram 2020, 9: 193-203.
[4]
Eom JH, Kim YW, Raju S. Processing and properties of macroporous silicon carbide ceramics: A review. J Asian Ceram Soc 2013, 1: 220-242.
[5]
Nastic A, Merati A, Bielawski M, et al. Instrumented and Vickers indentation for the characterization of stiffness, hardness and toughness of zirconia toughened Al2O3 and SiC armor. J Mater Sci Technol 2015, 31: 773-783.
[6]
Shen ZW, Hu DA, Yang G, et al. Ballistic reliability study on SiC/UHMWPE composite armor against armor- piercing bullet. Compos Struct 2019, 213: 209-219.
[7]
Khodaei M, Yaghobizadeh O, Naghavi Alhosseini SH, et al. The effect of oxide, carbide, nitride and boride additives on properties of pressureless sintered SiC: A review. J Eur Ceram Soc 2019, 39: 2215-2231.
[8]
Lewis JA. Colloidal processing of ceramics. J Am Ceram Soc 2000, 83: 2341-2359.
[9]
Wu CJ, Pang JZ, Li BZ, et al. High-speed grinding of HIP-SiC ceramics on transformation of microscopic features. Int J Adv Manuf Technol 2019, 102: 1913-1921.
[10]
Wang X, Jiang M, Zhou ZW, et al. 3D printing of polymer matrix composites: A review and prospective. Compos Part B: Eng 2017, 110: 442-458.
[11]
Frazier WE. Metal additive manufacturing: A review. J Mater Eng Perform 2014, 23: 1917-1928.
[12]
Chen ZW, Li ZY, Li JJ, et al. 3D printing of ceramics: A review. J Eur Ceram Soc 2019, 39: 661-687.
[13]
Zhang D, Liu XF, Qiu JR. 3D printing of glass by additive manufacturing techniques: A review. Front Optoelectron 2020, .
[14]
Barberi J, Baino F, Fiume E, et al. Robocasting of SiO2-based bioactive glass scaffolds with porosity gradient for bone regeneration and potential load-bearing applications. Materials 2019, 12: E2691.
[15]
Melcher R, Martins S, Travitzky N, et al. Fabrication of Al2O3-based composites by indirect 3D-printing. Mater Lett 2006, 60: 572-575.
[16]
Zhang KQ, Xie C, Wang G, et al. High solid loading, low viscosity photosensitive Al2O3 slurry for stereolithography based additive manufacturing. Ceram Int 2019, 45: 203-208.
[17]
Xing HY, Zou B, Li SS, et al. Study on surface quality, precision and mechanical properties of 3D printed ZrO2 ceramic components by laser scanning stereolithography. Ceram Int 2017, 43: 16340-16347
[18]
Zhang KQ, He RJ, Xie C, et al. Photosensitive ZrO2 suspensions for stereolithography. Ceram Int 2019, 45: 12189-12195.
[19]
Zhang KQ, He RJ, Ding GJ, et al. Digital light processing of 3Y-TZP strengthened ZrO2 ceramics. Mater Sci Eng: A 2020, 774: 138768.
[20]
Yan S, Huang YF, Zhao DK, et al. 3D printing of nano-scale Al2O3-ZrO2 eutectic ceramic: Principle analysis and process optimization of pores. Addit Manuf 2019, 28: 120-126.
[21]
Mei H, Zhao X, Zhou SX, et al. 3D-printed oblique honeycomb Al2O3/SiCw structure for electromagnetic wave absorption. Chem Eng J 2019, 372: 940-945.
[22]
Liu XY, Zou B, Xing HY, et al. The preparation of ZrO2-Al2O3 composite ceramic by SLA-3D printing and sintering processing. Ceram Int 2020, 46: 937-944.
[23]
Kulkarni A, Sorarù GD, Pearce JM. Polymer-derived SiOC replica of material extrusion-based 3-D printed plastics. Addit Manuf 2020, 32: 100988.
[24]
Zocca A, Gomes CM, Staude A, et al. SiOC ceramics with ordered porosity by 3D-printing of a preceramic polymer. J Mater Res 2013, 28: 2243-2252.
[25]
Jana P, Santoliquido O, Ortona A, et al. Polymer-derived SiCN cellular structures from replica of 3D printed lattices. J Am Ceram Soc 2018, 101: 2732-2738.
[26]
Gyak KW, Vishwakarma NK, Hwang YH, et al. 3D-printed monolithic SiCN ceramic microreactors from a photocurable preceramic resin for the high temperature ammonia cracking process. React Chem Eng 2019, 4: 1393-1399.
[27]
Chen QH, Zou B, Lai QG, et al. A study on biosafety of HAP ceramic prepared by SLA-3D printing technology directly. J Mech Behav Biomed Mater 2019, 98: 327-335.
[28]
Feng CW, Zhang KQ, He RJ, et al. Additive manufacturing of hydroxyapatite bioceramic scaffolds: Dispersion, digital light processing, sintering, mechanical properties, and biocompatibility. J Adv Ceram 2020, 9: 360-373.
[29]
Wei YH, Zhao DY, Cao QL, et al. Stereolithography- based additive manufacturing of high-performance osteoinductive calcium phosphate ceramics by a digital light-processing system. ACS Biomater Sci Eng 2020, 6: 1787-1797.
[30]
Cox SC, Jamshidi P, Eisenstein NM, et al. Adding functionality with additive manufacturing: Fabrication of titanium-based antibiotic eluting implants. Mater Sci Eng: C 2016, 64: 407-415.
[31]
Warnke PH, Seitz H, Warnke F, et al. Ceramic scaffolds produced by computer-assisted 3D printing and sintering: Characterization and biocompatibility investigations. J Biomed Mater Res Part B: Appl Biomater 2010, 93B: 212-217.
[32]
Stumpf M, Travitzky N, Greil P, et al. Sol-gel infiltration of complex cellular indirect 3D printed alumina. J Eur Ceram Soc 2018, 38: 3603-3609.
[33]
Taboas JM, Maddox RD, Krebsbach PH, et al. Indirect solid free form fabrication of local and global porous, biomimetic and composite 3D polymer-ceramic scaffolds. Biomaterials 2003, 24: 181-194.
[34]
Chen FJ, Liu K, Sun HJ, et al. Fabrication of complicated silicon carbide ceramic components using combined 3D printing with gelcasting. Ceram Int 2018, 44: 254-260.
[35]
Tu TZ, Jiang GJ. SiC reticulated porous ceramics by 3D printing, gelcasting and liquid drying. Ceram Int 2018, 44: 3400-3405.
[36]
Zhang H, Yang Y, Hu KH, et al. Stereolithography-based additive manufacturing of lightweight and high-strength Cf/SiC ceramics. Addit Manuf 2020, 34: 101199.
[37]
Saggio-Woyansky J, Scott C, Minnear W. Processing of porous ceramics. Am Ceram Soc Bull 1992, 71: 1674-1682.
[38]
Fey T, Betke U, Rannabauer S, et al. Reticulated replica ceramic foams: Processing, functionalization, and characterization. Adv Eng Mater 2017, 19: 1700369.
[39]
Ortona A, D'Angelo C, Gianella S, et al. Cellular ceramics produced by rapid prototyping and replication. Mater Lett 2012, 80: 95-98.
[40]
Rezaei E, Barbato M, Gianella S, et al. Pressure drop and convective heat transfer in different SiSiC structures fabricated by indirect additive manufacturing. J Heat Transf 2020, 142: 032702.
[41]
Pelanconi M, Rezaei E, Ortona A, et al. Cellular ceramic architectures produced by hybrid additive manufacturing: A review on the evolution of their design. J Ceram Soc Jpn 2020, 128: 595-604.
[42]
Ortona A, Trimis D, Uhlig V, et al. SiSiC heat exchangers for recuperative gas burners with highly structured surface elements. Int J Appl Ceram Technol 2014, 11: 927-937.
[43]
Ding GJ, He RJ, Zhang KQ, et al. Stereolithography 3D printing of SiC ceramic with potential for lightweight optical mirror. Ceram Int 2020, 46: 18785-18790.
[44]
Nelson JC, Vail NK, Barlow JW, et al. Selective laser sintering of polymer-coated silicon carbide powders. Ind Eng Chem Res 1995, 34: 1641-1651.
[45]
Evans RS, Bourell DL, Beaman JJ, et al. Rapid manufacturing of silicon carbide composites. Rapid Prototyp J 2005, 11: 37-40.
[46]
Exner H, Horn M, Streek A, et al. Laser micro sintering: A new method to generate metal and ceramic parts of high resolution with sub-micrometer powder. Virtual Phys Prototyp 2008, 3: 3-11.
[47]
Liu K, Wu T, Bourell DL, et al. Laser additive manufacturing and homogeneous densification of complicated shape SiC ceramic parts. Ceram Int 2018, 44: 21067-21075.
[48]
Fu H, Zhu W, Xu ZF, et al. Effect of silicon addition on the microstructure, mechanical and thermal properties of Cf/SiC composite prepared via selective laser sintering. J Alloys Compd 2019, 792: 1045-1053.
[49]
Meyers S, de Leersnijder L, Vleugels J, et al. Direct laser sintering of reaction bonded silicon carbide with low residual silicon content. J Eur Ceram Soc 2018, 38: 3709-3717.
[50]
Xu TT, Cheng S, Jin LZ, et al. High-temperature flexural strength of SiC ceramics prepared by additive manufacturing. Int J Appl Ceram Technol 2020, 17: 438-448.
[51]
Sun XM, Zeng T, Zhou YK, et al. 3D printing of porous SiC ceramics added with SiO2 hollow microspheres. Ceram Int 2020, 46: 22797-22804.
[52]
King D, Middendorf J, Cissel K, et al. Selective laser melting for the preparation of an ultra-high temperature ceramic coating. Ceram Int 2019, 45: 2466-2473.
[53]
Wits WW, de Smit M, Al-Hamdani K, et al. Laser powder bed fusion of a magnesium-SiC metal matrix composite. Procedia CIRP 2019, 81: 506-511.
[54]
Wei C, Chueh YH, Zhang XJ, et al. Easy-to-remove composite support material and procedure in additive manufacturing of metallic components using multiple material laser-based powder bed fusion. J Manuf Sci Eng 2019, 141: 071002.
[55]
Wei C, Gu H, Zhang XJ, et al. Hybrid ultrasonic and mini-motor vibration-induced irregularly shaped powder delivery for multiple materials additive manufacturing. Addit Manuf 2020, 33: 101138.
[56]
Lv X, Ye F, Cheng LF, et al. Fabrication of SiC whisker-reinforced SiC ceramic matrix composites based on 3D printing and chemical vapor infiltration technology. J Eur Ceram Soc 2019, 39: 3380-3386.
[57]
Baux A, Goillot A, Jacques S, et al. Synthesis and properties of macroporous SiC ceramics synthesized by 3D printing and chemical vapor infiltration/deposition. J Eur Ceram Soc 2020, 40: 2834-2854.
[58]
Fleisher A, Zolotaryov D, Kovalevsky A, et al. Reaction bonding of silicon carbides by Binder Jet 3D-Printing, phenolic resin binder impregnation and capillary liquid silicon infiltration. Ceram Int 2019, 45: 18023-18029.
[59]
Zocca A, Lima P, Diener S, et al. Additive manufacturing of SiSiC by layerwise slurry deposition and binder jetting (LSD-print). J Eur Ceram Soc 2019, 39: 3527-3533.
[60]
Zhu SX, Michael HC, Mrityunjay S. Additive manufacturing of silicon carbide-based ceramics by 3-D printing technologies. In: Advanced Processing and Manufacturing Technologies for Nanostructured and Multifunctional Materials II. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2015: 133-144.
[61]
Polzin C, Günther D, Seitz H. 3D printing of porous Al2O3 and SiC ceramics. J Ceram Sci Technol 2015, 6: 141-146.
[62]
Duan WY, Yin XW, Cao FX, et al. Absorption properties of twinned SiC nanowires reinforced Si3N4 composites fabricated by 3d-prining. Mater Lett 2015, 159: 257-260.
[63]
Singh N, Singh R, Kumar R, et al. Recycled HDPE reinforced Al2O3 and SiC three dimensional printed patterns for sandwich composite material. Eng Res Express 2019, 1: 015007.
[64]
Masuda H, Ohta Y, Kitayama M. Additive manufacturing of SiC ceramics with complicated shapes using the FDM type 3D-printer. J Mater Sci Chem Eng 2019, 7: 1-12.
[65]
Travitzky N, Windsheimer H, Fey T, et al. Preceramic paper-derived ceramics. J Am Ceram Soc 2008, 91: 3477-3492.
[66]
Windsheimer H, Travitzky N, Hofenauer A, et al. Laminated object manufacturing of preceramic-paper- derived Si-SiC composites. Adv Mater 2007, 19: 4515-4519.
[67]
Cai KP, Román-Manso B, Smay JE, et al. Geometrically complex silicon carbide structures fabricated by robocasting. J Am Ceram Soc 2012, 95: 2660-2666.
[68]
Wahl L, Lorenz M, Biggemann J, et al. Robocasting of reaction bonded silicon carbide structures. J Eur Ceram Soc 2019, 39: 4520-4526.
[69]
Feilden E, Glymond D, Saiz E, et al. High temperature strength of an ultra high temperature ceramic produced by additive manufacturing. Ceram Int 2019, 45: 18210-18214.
[70]
Elizarova IS, Vandeperre L, Saiz E. Conformable green bodies: Plastic forming of robocasted advanced ceramics. J Eur Ceram Soc 2020, 40: 552-557.
[71]
Gómez-Gómez A, Moyano JJ, Osendi MI, et al. The effect of rod orientation on the strength of highly porous filament printed 3D SiC ceramic architectures. Boletín de la Sociedad Española de Cerámica y Vidrio 2021, 60: 119-127.
[72]
Zhang H, Yang Y, Liu B, et al. The preparation of SiC-based ceramics by one novel strategy combined 3D printing technology and liquid silicon infiltration process. Ceram Int 2019, 45: 10800-10804.
[73]
McClain MS, Gunduz IE, Son SF. Additive manufacturing of carbon fiber reinforced silicon carbide solid rocket nozzles. In: Proceedings of the AIAA Scitech 2019 Forum, 2019: AIAA 2019-0408.
[74]
Halloran JW. Ceramic stereolithography: Additive manufacturing for ceramics by photopolymerization. Annu Rev Mater Res 2016, 46: 19-40.
[75]
Santoliquido O, Colombo P, Ortona A. Additive Manufacturing of ceramic components by Digital Light Processing: A comparison between the “bottom-up” and the “top-down” approaches. J Eur Ceram Soc 2019, 39: 2140-2148.
[76]
Friedel T, Travitzky N, Niebling F, et al. Fabrication of polymer derived ceramic parts by selective laser curing. J Eur Ceram Soc 2005, 25: 193-197.
[77]
Park S, Lee DH, Ryoo HI, et al. Fabrication of three-dimensional SiC ceramic microstructures with near-zero shrinkage via dual crosslinking induced stereolithography. Chem Commun 2009: 4880-4882.
[78]
Eckel ZC, Zhou C, Martin JH, et al. Additive manufacturing of polymer-derived ceramics. Science 2016, 351: 58-62.
[79]
De Hazan Y, Penner D. SiC and SiOC ceramic articles produced by stereolithography of acrylate modified polycarbosilane systems. J Eur Ceram Soc 2017, 37: 5205-5212.
[80]
Ligon SC, Blugan G, Kuebler J. Maskless lithography of silazanes for fabrication of ceramic micro-components. Ceram Int 2019, 45: 2345-2350.
[81]
Chen JS, Wang YJ, Pei XL, et al. Preparation and stereolithography of SiC ceramic precursor with high photosensitivity and ceramic yield. Ceram Int 2020, 46: 13066-13072.
[82]
Wang XF, Schmidt F, Hanaor D, et al. Additive manufacturing of ceramics from preceramic polymers: A versatile stereolithographic approach assisted by thiol-ene click chemistry. Addit Manuf 2019, 27: 80-90.
[83]
Schmidt J, Brigo L, Gandin A, et al. Multiscale ceramic components from preceramic polymers by hybridization of vat polymerization-based technologies. Addit Manuf 2019, 30: 100913.
[84]
Ding GJ, He RJ, Zhang KQ, et al. Stereolithography- based additive manufacturing of gray-colored SiC ceramic green body. J Am Ceram Soc 2019, 102: 7198-7209.
[85]
Ding GJ, He RJ, Zhang KQ, et al. Dispersion and stability of SiC ceramic slurry for stereolithography. Ceram Int 2020, 46: 4720-4729.
[86]
He RJ, Ding GJ, Zhang KQ, et al. Fabrication of SiC ceramic architectures using stereolithography combined with precursor infiltration and pyrolysis. Ceram Int 2019, 45: 14006-14014.
[87]
Ding GJ, He RJ, Zhang KQ, et al. Stereolithography 3D printing of SiC ceramic with potential for lightweight optical mirror. Ceram Int 2020, 46: 18785-18790.
[88]
Larson CM, Choi JJ, Gallardo PA, et al. Direct ink writing of silicon carbide for microwave optics. Adv Eng Mater 2016, 18: 39-45.
[89]
Chen HH, Wang XF, Xue FD, et al. 3D printing of SiC ceramic: Direct ink writing with a solution of preceramic polymers. J Eur Ceram Soc 2018, 38: 5294-5300.
[90]
Xiong HW, Zhao LZ, Chen HH, et al. 3D SiC containing uniformly dispersed, aligned SiC whiskers: Printability, microstructure and mechanical properties. J Alloys Compd 2019, 809: 151824.
[91]
Xiong HW, Chen HH, Chen ZK, et al. 3D-SiC decorated with SiC whiskers: Chemical vapor infiltration on the porous 3D-SiC lattices derived from polycarbosilane- based suspensions. Ceram Int 2020, 46: 6234-6242.
[92]
Zhu Q, Dong X, Hu JB, et al. High strength aligned SiC nanowire reinforced SiC porous ceramics fabricated by 3D printing and chemical vapor infiltration. Ceram Int 2020, 46: 6978-6983.
[93]
Xia YL, Lu ZL, Cao JW, et al. Microstructure and mechanical property of Cf/SiC core/shell composite fabricated by direct ink writing. Scripta Mater 2019, 165: 84-88.
[94]
Lu ZL, Xia YL, Miao K, et al. Microstructure control of highly oriented short carbon fibres in SiC matrix composites fabricated by direct ink writing. Ceram Int 2019, 45: 17262-17267.
[95]
Song SC, Gao ZQ, Lu BH, et al. Performance optimization of complicated structural SiC/Si composite ceramics prepared by selective laser sintering. Ceram Int 2020, 46: 568-575.
[96]
Gómez-Gómez A, Moyano JJ, Román-Manso B, et al. Highly-porous hierarchical SiC structures obtained by filament printing and partial sintering. J Eur Ceram Soc 2019, 39: 688-695.
[97]
Hu KH, Wei YM, Lu ZG, et al. Design of a shaping system for stereolithography with high solid loading ceramic suspensions. 3D Print Addit Manuf 2018, 5: 311-318.
[98]
Li H, Liu YS, Liu YS, et al. Effect of sintering temperature in argon atmosphere on microstructure and properties of 3D printed alumina ceramic cores. J Adv Ceram 2020, 9: 220-231.
[99]
Li H, Liu YS, Liu YS, et al. Influence of debinding holding time on mechanical properties of 3D-printed alumina ceramic cores. Ceram Int 2021, 47: 4884-4894.
[100]
Zhang JX, Jiang DL, Lin QL, et al. Properties of silicon carbide ceramics from gelcasting and pressureless sintering. Mater Des 2015, 65: 12-16.
[101]
Song N, Zhang HB, Liu H, et al. Effects of SiC whiskers on the mechanical properties and microstructure of SiC ceramics by reactive sintering. Ceram Int 2017, 43: 6786-6790.
[102]
Ma RZ, Wu J, Wei BQ, et al. Processing and properties of carbon nanotubes-nano-SiC ceramic. J Mater Sci 1998, 33: 5243-5246.
[103]
Dong SM, Katoh Y, Kohyama A. Preparation of SiC/SiC composites by hot pressing, using tyranno-SA fiber as reinforcement. J Am Ceram Soc 2003, 86: 26-32.
[104]
Liu W, Chen CY, Shuai SS, et al. Study of pore defect and mechanical properties in selective laser melted Ti6Al4V alloy based on X-ray computed tomography. Mater Sci Eng: A 2020, 797: 139981.
[105]
Saâdaoui M, Khaldoun F, Adrien J, et al. X-ray tomography of additive-manufactured zirconia: Processing defects - Strength relations. J Eur Ceram Soc 2020, 40: 3200-3207.
[106]
Khaldoun F, Saâdaoui M, Adrien J, et al. Flexural strength and X-ray computed tomography analysis of zirconia specimens processed by additive manufacturing. In: Proceedings of the 16th European Inter-Regional Conference of Ceramics, 2018.
[107]
Diener S, Franchin G, Achilles N, et al. X-ray microtomography investigations on the residual pore structure in silicon nitride bars manufactured by direct ink writing using different printing patterns. Open Ceram 2021, 5: 100042.
[108]
Arai Y, Inoue R, Goto K, et al. Carbon fiber reinforced ultra-high temperature ceramic matrix composites: A review. Ceram Int 2019, 45: 14481-14489.
[109]
Binner J, Porter M, Baker B, et al. Selection, processing, properties and applications of ultra-high temperature ceramic matrix composites, UHTCMCs - a review. Int Mater Rev 2020, 65: 389-444.
[110]
Wang PR, Liu FQ, Wang H, et al. A review of third generation SiC fibers and SiCf/SiC composites. J Mater Sci Technol 2019, 35: 2743-2750.
[111]
Fidan I, Imeri A, Gupta A, et al. The trends and challenges of fiber reinforced additive manufacturing. Int J Adv Manuf Technol 2019, 102: 1801-1818.
[112]
Balla VK, Kate KH, Satyavolu J, et al. Additive manufacturing of natural fiber reinforced polymer composites: Processing and prospects. Compos Part B: Eng 2019, 174: 106956.
[113]
Wang X, Jiang M, Zhou Z, et al. Additive manufacturing of natural fiber reinforced polymer composites: Processing and prospects. Compos B 2017, 110: 442-458.
[114]
Kabir SMF, Mathur K, Seyam AFM. A critical review on 3D printed continuous fiber-reinforced composites: History, mechanism, materials and properties. Compos Struct 2020, 232: 111476.
[115]
van de Werken N, Tekinalp H, Khanbolouki P, et al. Additively manufactured carbon fiber-reinforced composites: State of the art and perspective. Addit Manuf 2020, 31: 100962.
[116]
Lu ZL, Cao JW, Song ZQ, et al. Research progress of ceramic matrix composite parts based on additive manufacturing technology. Virtual Phys Prototyp 2019, 14: 333-348.
[117]
Pelanconi M, Rezaei E, Ortona A. Cellular ceramic architectures produced by hybrid additive manufacturing: A review on the evolution of their design. J Ceram Soc Jpn 2020, 128: 595-604.
[118]
Szczurek A, Ortona A, Ferrari L, et al. Carbon periodic cellular architectures. Carbon 2015, 88: 70-85.
[119]
Zhao WM, Wang C, Zhao Z. Bending strength of 3D-printed zirconia ceramic cellular structures. IOP Conf Ser: Mater Sci Eng 2019, 678: 012019.
[120]
Zhao WM, Wang C, Xing BH, et al. Mechanical properties of zirconia octet truss structures fabricated by DLP 3D printing. Mater Res Express 2020, 7: 085201.
[121]
Mei H, Zhao RS, Xia YZ, et al. Ultrahigh strength printed ceramic lattices. J Alloys Compd 2019, 797: 786-796.
[122]
Mei H, Huang WZ, Zhao YZ, et al. Strengthening three-dimensional printed ultra-light ceramic lattices. J Am Ceram Soc 2019, 102: 5082-5089.
[123]
Mei H, Zhao X, Zhou SX, et al. 3D-printed oblique honeycomb Al2O3/SiCw structure for electromagnetic wave absorption. Chem Eng J 2019, 372: 940-945.
[124]
Xiao SS, Mei H, Han DY, et al. 3D printed SiC nanowire reinforced composites for broadband electromagnetic absorption. Ceram Int 2019, 45: 11475-11483.
[125]
Yang S, Zhao YF. Additive manufacturing-enabled design theory and methodology: A critical review. Int J Adv Manuf Technol 2015, 80: 327-342.
[126]
Yang Y, Song X, Li XJ, et al. Recent progress in biomimetic additive manufacturing technology: From materials to functional structures. Adv Mater 2018, 30: 1706539.
[127]
Tang YL, Zhao YF. A survey of the design methods for additive manufacturing to improve functional performance. Rapid Prototyp J 2016, 22: 569-590.
[128]
Rodgers TM, Madison JD, Tikare V. Simulation of metal additive manufacturing microstructures using kinetic Monte Carlo. Comput Mater Sci 2017, 135: 78-89.
[129]
Tang YL, Zhao YF. A survey of the design methods for additive manufacturing to improve functional performance. Rapid Prototyp J 2016, 22: 569-590.
[130]
DebRoy T, Zhang W, Turner J, et al. Building digital twins of 3D printing machines. Scripta Mater 2017, 135: 119-124.
[131]
Majeed A, Lv J, Peng T. A framework for big data driven process analysis and optimization for additive manufacturing. Rapid Prototyp J 2019, 25: 308-321.
[132]
Mitchell A, Lafont U, Hołyńska M, et al. Additive manufacturing—A review of 4D printing and future applications. Addit Manuf 2018, 24: 606-626.
[133]
Liu G, Zhao Y, Wu G, et al. Origami and 4D printing of elastomer-derived ceramic structures. Sci Adv 2018, 4: eaat0641.
[134]
Zhang KQ, Wei K, Chen JX, et al. Stereolithography additive manufacturing of multi-ceramic triangle structures with tunable thermal expansion. J Eur Ceram Soc 2021, 41: 2796-2806.
Journal of Advanced Ceramics
Pages 637-674
Cite this article:
HE R, ZHOU N, ZHANG K, et al. Progress and challenges towards additive manufacturing of SiC ceramic. Journal of Advanced Ceramics, 2021, 10(4): 637-674. https://doi.org/10.1007/s40145-021-0484-z
Part of a topical collection:

3066

Views

926

Downloads

181

Crossref

169

Web of Science

190

Scopus

15

CSCD

Altmetrics

Received: 05 January 2021
Revised: 25 March 2021
Accepted: 12 April 2021
Published: 05 August 2021
© The Author(s) 2021

This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.

The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder.

To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

Return