[1] E HOOPER T, I ROSCOW J, A MATHIESON et al. High voltage coefficient piezoelectric materials and their applications. Journal of the European Ceramic Society, 41, 6115-6129(2021).
[2] H WASTON B, J BROVA Ml, M FANTON et al. Textured Mn- doped PIN-PMN-PT ceramics: harnessing intrinsic piezoelectricity for high-power transducer applications. Journal of the European Ceramic Society, 41, 1270-1279(2021).
[3] R JIA H, S YANG, T ZHU W et al. Improved piezoelectric properties of Pb(Mg1/3Nb2/3)O3-PbTiO3 textured ferroelectric ceramics via Sm-doping method. Journal of Alloys and Compounds, 881, 160666(2021).
[4] N LÜ, C ZHONG, K WANG L. Bending vibration characteristics of the piezoelectric composite double laminated vibrator. Ceramics International, 47, 31259-31267(2021).
[5] N CHEN A, M LI, M WU J et al. Enhancement mechanism of mechanical performance of highly porous mullite ceramics with bimodal pore structures prepared by selective laser sintering. Journal of Alloys and Compounds, 776, 486-494(2018).
[6] Y DONG, Y JIANG H, N CHEN A et al. Near-zero-shrinkage Al2O3 ceramic foams with coral-like and hollow-sphere structures via selective laser sintering and reaction bonding. Journal of European Ceramic Society, 41, 239-246(2021).
[7] X ZHANG, F WANG, P WU Z et al. Direct selective laser sintering of hexagonal barium titanate ceramics. Journal of American Ceramic Society, 104, 1271-1280(2021).
[8] K LIU, S SHI Y, H LI C et al. Indirect selective laser sintering of epoxy resin-Al2O3 ceramic powders combined with cold isostatic pressing. Ceramics International, 40, 7099-7106(2014).
[9] S SHI Y, K LIU, H LI C et al. Additive manufacturing of zirconia parts via selective laser sintering combined with cold isostatic pressing. Journal of Mechanical Engineering, 50, 118-123(2014).
[10] K LIU, J SUN H, S SHI Y et al. Research on selective laser sintering of kaolin-epoxy resin ceramic powders combined with cold isostatic pressing and sintering. Ceramics International, 42, 10711-10718(2016).
[11] K LIU, T WU, L BOURELL D et al. Laser additive manufacturing and homogeneous densification of complicated shape SiC ceramic parts. Ceramics International, 44, 21067-21075(2018).
[12] I KOVSKY, Y MOROZOV, M KUZNETSOV. Layering fabrication, structure, and electromagnetic properties of perovskite phases by hybrid process: self-propagated high-temperature synthesis and selective laser sintering. Phase Transitions, 86, 1085-1093(2013).
[13] M KUZNETSOV, I SHISHKOVSKY, Y MOROZOV et al. Design of three-dimensional functional articles via layer-by-layer laser sintering of exothermic powder mixtures. Advanced Manufacturing Processes, 23, 571-578(2008).
[14] A BERNARD S, K BALLA V, S BOSE et al. Direct laser processing of bulk lead zirconate titanate ceramics. Materials Science & Engineering B, 172, 85-88(2010).
[15] F DINI, A GHAFFARI S, J JAFAR et al. A review of binder jet process parameters; powder, binder, printing and sintering condition. Metal Powder Report, 75, 95-100(2019).
[16] Y LV X, F YE, F CHENG L et al. Binder jetting of ceramics: powders, binders, printing parameters, equipment, and post-treatment. Ceramics International, 45, 12609-12624(2019).
[17] M GAYTAN S, A CADENA M, H KARIM et al. Fabrication of barium titanate by binder jetting additive manufacturing technology. Ceramics International, 41, 6610-6619(2015).
[18] V SUFIIAROV, A KANTYUKOV, A POPOVICH et al. Structure and properties of barium titanate lead-free piezoceramic manufactured by binder jetting process. Materials, 14, 4419(2021).
[19] M SCHULT, E BUCKOW, H SEITZ. Experimental studies on 3D printing of barium titanate ceramics for medical applications. Current Directions in Biomedical Engineering, 2, 95-99(2016).
[20] X ZHANG, X WU, J SHI. Additive manufacturing of zirconia ceramics: a state-of-the-art review. Journal of Materials Research and Technology, 9, 9029-9048(2020).
[21] M LAYANI, F WANG X, S MAGDASSI. Novel materials for 3D printing by photopolymerization. Advanced Materials, 30, 1706344(2018).
[22] S ZAKERI, M VIPPOLA, E LEVANEN. A comprehensive review of the photopolymerization of ceramic resins used in stereolithography. Additive Manufacturing, 35, 101177(2020).
[23] W WANG, X SUN J, B GUO B et al. Fabrication of piezoelectric nano-ceramics via stereolithography of low viscous and non-aqueous suspensions. Journal of the European Ceramic Society, 40, 682-688(2020).
[24] M CHA J, W LEE J, B BAE et al. Fabrication and characterization of PZT suspensions for stereolithography based on 3D printing. Journal of the Korean Ceramic Society, 56, 360-364(2019).
[25] O DUFAUD, L GALL H, S CORBEL. Stereolithography of lead zirconate titanate ceramics for MEMS applications. Proceedings of SPIE-the International Society for Optical Engineering, 5116, 28-37(2003).
[26] O DUFAUD, P MARCHAL, S CORBEL. Rheological properties of PZT suspensions for stereolithography. Journal of the European Ceramic Society, 22, 2081-2092(2002).
[27] O DUFAUD, S CORBEL. Oxygen diffusion in ceramic suspensions for stereolithography. Chemical Engineering Journal, 92, 55-62(2003).
[28] C SUN, X ZHANG. The influences of the material properties on ceramic micro-stereolithography. Sensors & Actuators A Physical, 101, 364-370(2002).
[29] A SMIRNOV, S CHUGUNOV, A KHOLODKOVA et al. Progress and challenges of 3D-printing technologies in the manufacturing of piezoceramics. Ceramics International, 47, 10478-10511(2021).
[30] F LIN L, D WU H, R XU Y et al. Fabrication of dense aluminum nitride ceramics via digital light processing-based stereolithography. Materials Chemistry and Physics, 249, 122969(2020).
[31] S ZENG Y, M JIANG L, Z SUN Y et al. 3D-printing piezoelectric composite with honeycomb structure for ultrasonic devices. Micromachines, 11, 713(2020).
[32] K LIU, Y ZHOU C, M HU J et al. Fabrication of barium titanate ceramics via digital light processing 3D printing by using high refractive index monomer. Journal of the European Ceramic Society, 41, 5909-5917(2021).
[33] Y CHEN Z, G JIANG Q, X SONG et al. Piezoelectric Array for Transducer Application Using Additive Manufacturing(2017).
[34] X SONG, Y CHEN Z, W LEI L et al. Piezoelectric component fabrication using projection-based stereolithography of barium titanate ceramic suspensions. Rapid Prototyping Journal, 23, 44-53(2017).
[35] T ROSENTAL, S MIZRAHI, A KAMYSHNY et al. Particle-free compositions for printing dense 3D ceramic structures by digital light processing. Virtual and Physical Prototyping, 16, 255-266(2021).
[36] R NOGUERA, M LEJEUNE, T CHARTIER. 3D fine scale ceramic components formed by ink-jet prototyping process. Journal of the European Ceramic Society, 25, 2055-2059(2005).
[37] M LEJEUNE, T CHARTIER, C DOSSOU-YOVO et al. Ink-jet printing of ceramic micro-pillar arrays. Journal European Ceramic Society, 29, 905-911(2009).
[38] H LEE D, B DERBY. Preparation of PZT suspensions for direct ink jet printing. Journal of the European Ceramic Society, 24, 1069-1072(2004).
[39] B DERBY, H LEE D, T WANG et al. Development of PZT suspensions for ceramic ink-jet printing. Materials Research Society Symposium Proceeding, 758, 113-118(2003).
[40] M WANG T, B DERBY. Ink-jet printing and sintering of PZT. Journal of the American Ceramic Society, 88, 2053-2058(2005).
[41] K LIU, Q ZHANG Q, Y ZHOU C et al. 4D printing of lead zirconate titanate piezoelectric composites transducer based on direct ink writing. Frontiers in Materials, 8, 659441(2021).
[42] L WALTON R, J BROVA M, H WASTON B et al. Direct writing of textured ceramics using anisotropic nozzles. Journal of the European Ceramic Society, 41, 1945-1953(2020).
[43] L WALTON R, A FANTON M, J MEYER R et al. Dispersion and rheology for direct writing lead-based piezoelectric ceramic pastes with anisotropic template particles. Journal of the American Ceramic Society, 103, 6157-6168(2020).
[44] A RENTERIA, A DIAZ J, T HE B et al. Particle size influence on material properties of BaTiO3 ceramics fabricated using freeze- form extrusion 3D printing. Materials Research Express, 6, 115211(2019).
[45] E HALL S, E REGIS J, A RENTERIA et al. Paste extrusion 3D printing and characterization of lead zirconate titanate piezoelectric ceramics. Ceramics International, 47, 22042-22048(2021).
[46] A RENTERIA, H FONTES, A DIAZ J et al. Optimization of 3D printing parameters for BaTiO3 piezoelectric ceramics through design of experiments. Materials Research Express, 6, 085706(2019).
[47] A RENTERIA, F GARCIA L, H BALCORTA V et al. Influence of bimodal particle distribution on material properties of BaTiO3 fabricated by paste extrusion 3D printing. Ceramics International, 47, 18477-18486(2021).
[48] Y LI Y, T LI L, B LI. Direct ink writing of 3-3 piezoelectric composite. Journal of Alloys and Compounds, 620, 125-128(2015).
[49] B NAN, S OLHERO, R PINHO et al. Direct ink writing of macro- porous lead-free piezoelectric Ba0.85Ca0.15Zr0.1Ti0.9O3. Journal of the American Ceramic Society, 102, 3191-3203(2019).
[50] C GADEA, T SPELTA, B SIMONSEN S et al. Hybrid inks for 3D printing of tall BaTiO3-based ceramics. Open Ceramics, 6, 100110(2021).
[51] A JAFARI M, W HAN, F MOHAMMADI et al. A novel system for fused deposition of advanced multiple ceramics. Rapid Prototyping Journal, 6, 161-175(2000).
[52] A HALL, M ALLAHVERDI, K AKDOGAN E et al. Piezoelectric/ electrostrictive multimaterial PMN-PT monomorph actuators. Journal of the European Ceramic Society, 25, 2991-2997(2005).
[53] 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).
[54] K MIAO, H ZHOU, P GAO Y et al. Laser powder-bed-fusion of Si3N4 reinforced AlSi10Mg composites: processing, mechanical properties and strengthening mechanisms. Materials Science & Engineering A, 825, 141874(2021).
[55] L LU Z, W CAO J, Q SONG Z et al. Research progress of ceramic matrix composite parts based on additive manufacturing technology. Virtual and Physical Prototyping, 14, 333-348(2019).
[56] A CHAVEZ L, R WILBURN B, P LBAVE et al. Fabrication and characterization of 3D printing induced orthotropic functional ceramics. Smart Materials and Structures, 28, 125007(2019).
[57] L ZHANG, T WANG, X SUN J et al. A study of lead-free (K0.5N0.5)NbO3 piezoelectric ceramics processed by additive manufacturing. Journal of Micromechanics and Molecular Physics, 5, 2050011(2020).
[58] I WOODWARD D, P PURSSELL C, R BILLSON D et al. Additively-manufactured piezoelectric devices. Physica Status Solidi (A) Applications and Materials, 212, 2017-2113(2015).
[59] Y CHEN, L BAO X, M WONG C et al. PZT ceramics fabricated based on stereolithography for an ultrasound transducer array application. Ceramics International, 44, 22725-22730(2018).
[60] C CHEN W, F WANG F, K YAN et al. Micro-stereolithography of KNN-based lead-free piezoceramics. Ceramics International, 45, 4880-4885(2019).
[61] H ZHANG Y, C CHEN W, W WU D. Geometric deformation prediction and compensation for micro-stereolithography of piezoceramic. Electronic Components and Materials, 38, 77-82(2019).
[62] A SOTOV, A KANTYUKOV, A POPOVICH et al. LCD-SLA 3D printing of BaTiO3 piezoelectric ceramics. Ceramics International, 47, 30358-30366(2021).
[63] D KUSCER, S DRNOVSEK, F LEVASSORT. Inkjet-printing- derived lead-zirconate-titanate-based thick films for printed electronics. Materials & Design, 198, 109324(2021).
[64] H KIM, A RENTERIA-MARQUEZ, D ISLAM M et al. Fabrication of bulk piezoelectric and dielectric BaTiO3 ceramics using paste extrusion 3D printing technique. Journal of the American Ceramic Society, 102, 3685-3694(2019).
[65] M LORENZ, A MARTIN, G WEBBER K et al. Electromechanical properties of robocasted barium titanate ceramics. Advanced Engineering Materials, 22, 2000325(2020).
[66] T RSOENTAL, S MAGDASSI. A new approach to 3D printing dense ceramics by ceramic precursor binders. Advanced Engineering Materials, 21, 1900604(2019).
[67] X WEI X, H LIU Y, J ZHAO D et al. 3D printing of piezoelectric barium titanate with high density from milled powders. Journal of the European Ceramic Society, 40, 5423-5430(2020).
[68] M LOUS G, A CORNEJO I, F MCNULTY T et al. Fabrication of piezoelectric ceramic/polymer composite transducers using fused deposition of ceramics. Journal of the American Ceramic Society, 83, 124-128(2000).
[69] H CHABOK, C ZHOU, Y CHEN.
[70] C POLLEY, T DISTLER, R DETSCH et al. 3D printing of piezoelectric barium titanate-hydroxyapatite scaffolds with interconnected porosity for bone tissue engineering. Materials, 13, 1773(2020).
[71] H XU, M XIE Y, W ZHOU S et al. Piezoelectric properties of triply periodic minimum surface structures. Composites Science and Technology, 200, 108417(2020).
[72] X SONG, L HE, H YANG W et al. Additive manufacturing of bi-continuous piezocomposites with triply periodic phase interfaces for combined flexibility and piezoelectricity. Journal of Manufacturing Science and Engineering, 141, 111004(2019).
[73] J CHENG, Y CHEN, W WU J et al. 3D printing of BaTiO3 piezoelectric ceramics for a focused ultrasonic array. Sensors, 19, 4078(2019).
[74] Y CHEN Z, X SONG, W LEI L et al. 3D printing of piezoelectric element for energy focusing and ultrasonic sensing. Nano Energy, 27, 78-86(2016).
[75] A ANDEREGG D, A BRYANT H, C RUFFIN D et al. In-situ monitoring of polymer flow temperature and pressure in extrusion based additive manufacturing. Additive Manufacturing, 26, 76-83(2019).
[76] S CLIJSTERS, T CRAEGHS, S BULS et al. In situ quality control of the selective laser melting process using a high-speed, real-time melt pool monitoring system. The International Journal of Advanced Manufacturing Technology, 75, 1089-1101(2014).
[77] T FANG, A JAFARI M, C DANFORTH S et al. Signature analysis and defect detection in layered manufacturing of ceramic sensors and actuators. Machine Vision and Applications, 15, 63-75(2003).