[1] SEBASTIAN T,KOZIELSKI L,ERHART J. Co-sintered PZT ceramics for the piezoelectric transformers［J］. Ceramics International,2015,41(8): 9321-9327.

[2] BOWEN C R,KIM H A,WEAVER P M,et al. Piezoelectric and ferroelectric materials and structures for energy harvesting applications［J］. Energy Environ Sci,2014,7(1): 25-44.

[3] KIM E,LEE J,KIM D,et al. Solvent-responsive polymer nanocapsules with controlled permeability: encapsulation and release of a fluorescent dye by swelling and deswelling［J］. Chemical Communications,2009(12): 1472-1474.

[4] ELAHI H,MUNIR K,EUGENI M,et al. A review on applications of piezoelectric materials in aerospace industry［J］. Integrated Ferroelectrics,2020,211(1): 25-44.

[5] TARIVERDIAN T,BEHNAMGHADER A,BROUKI MILAN P,et al. 3D-printed Barium strontium titanate-based piezoelectric scaffolds for bone tissue engineering［J］. Ceramics International,2019,45(11): 14029-14038.

[6] KIM H,TORRES F,VILLAGRAN D,et al. 3D printing of BaTiO3/PVDF composites with electric in situ poling for pressure sensor applications［J］. Macromolecular Materials and Engineering,2017,302(11): 1700229-1700234.

[7] ZHANG Y,ZUO T T,TANG Z,et al. Microstructures and properties of high-entropy alloys［J］. Progress in Materials Science,2014,61: 1-93.

[8] WUCHERER L,NINO J C,SUBHASH G. Mechanical properties of BaTiO3 open-porosity foams［J］. Journal of the European Ceramic Society,2009,29(10): 1987-1993.

[9] SMITH A T,LACHANCE A M,ZENG S S,et al. Synthesis,properties,and applications of graphene oxide/reduced graphene oxide and their nanocomposites［J］. Nano Materials Science,2019,1(1): 31-47.

[10] SHUAI X G,ZENG Y,LI P R,et al. Fabrication of fine and complex lattice structure Al2O3 ceramic by digital light processing 3D printing technology［J］. Journal of Materials Science,2020,55(16): 6771-6782.

[11] DONG Y,JIANG H Y,CHEN A N,et al. Near-zero-shrinkage Al2O3 ceramic foams with coral-like and hollow-sphere structures via selective laser sintering and reaction bonding［J］. Journal of the European Ceramic Society,2021,41(16): 239-246.

[12] SHEN M H,QIN W,XING B H,et al. Mechanical properties of 3D printed ceramic cellular materials with triply periodic minimal surface architectures［J］. Journal of the European Ceramic Society,2021,41(2): 1481-1489.

[13] CHEN A N,LI M,WU J M,et al. Enhancement mechanism of mechanical performance of highly porous mullite ceramics with bimodal pore structures prepared by selective laser sintering［J］. Journal of Alloys and Compounds,2019,776: 486-494.

[14] LIU C L,DU Q P,ZHOU H,et al. 3D printing of lead zirconate titanate piezoelectric ceramics via digital light processing (DLP)［J］. Ceramics International,2023,49(17): 28492-28499.

[15] CHEN Z Y,SONG X,LEI L W,et al. 3D printing of piezoelectric element for energy focusing and ultrasonic sensing［J］. Nano Energy,2016,27: 78-86.

[16] JIANG Z J,CHENG L Y,ZENG Y,et al. 3D printing of porous scaffolds BaTiO3 piezoelectric ceramics and regulation of their mechanical and electrical properties［J］. Ceramics International,2022,48(5): 6477-6487.

[17] SU Z H,ZHAO K L,YE Z J,et al. Overcoming the penetration-saturation trade-off in binder jet additive manufacturing via rapid in situ curing［J］. Additive Manufacturing,2022,59: 103157.

[18] YANG L L,ZENG X J,ZHANG Y. 3D printing of alumina ceramic parts by heat-induced solidification with carrageenan［J］. Materials Letters,2019,255: 126564.

[19] ZHAO L,JIANG Z L,MA S H,et al. Theoretical model based on stress waves and experimental verification of residual stress in stereolithography printed ZrO2 porous ceramics［J］. Ceramics International,2022,48(16): 23983-23988.

[20] 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.

[21] ZENG Y S,JIANG L M,SUN Y Z,et al. 3D-printing piezoelectric composite with honeycomb structure for ultrasonic devices［J］. Micromachines,2020,11(8): 713.

[22] CHENG J,CHEN Y,WU J W,et al. 3D printing of BaTiO3 piezoelectric ceramics for a focused ultrasonic array［J］. Sensors,2019,19(19): 4078.

[23] ZHANG D C,YANG Y D,RAO W F. Parameter optimization for printing Barium titanate piezoelectric ceramics through digital light processing［J］. Micromachines,2023,14(6): 1146.

[24] GONG P,LI Y,XIN C X,et al. Multimaterial 3D-printing Barium titanate/carbonyl iron composites with bilayer-gradient honeycomb structure for adjustable broadband microwave absorption［J］. Ceramics International,2022,48(7): 9873-9881.

[25] LIU K,ZHOU C Y,HU J M,et al. Fabrication of barium titanate ceramics via digital light processing 3D printing by using high refractive index monomer［J］. Journal of the European Ceramic Society,2021,41(12): 5909-5917.

[26] LIU K,HU J M,DU Y Y,et al. Influence of particle size on 3D-printed piezoelectric ceramics via digital light processing with furnace sintering［J］. International Journal of Applied Ceramic Technology,2022: 2461-2471.

[27] LIU K,SUN Y F,SUN H J,et al. Effect of particle grading on the properties of photosensitive slurry and BaTiO3 piezoelectric ceramic via digital light processing 3D printing［J］. Journal of the European Ceramic Society,2023,43(8): 3266-3274.

[28] LIU K,HE J C,LI T Y,et al. Fabrication of ceramic-polymer piezo-composites with triply periodic minimal interfaces via digital light processing［J］. Chinese Journal of Mechanical Engineering: Additive Manufacturing Frontiers,2023,2(4): 100104.

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

[30] BISWAS D,SHARMA P,PANWAR N S. Effect of sintering on the piezoelectric properties and microstructure of lead free (Ba1-xCaxZr0.1Ti0.9O3) (x=0.065) ceramics［J］. Science of Sintering,2022,54(2): 201-209.

[31] ROSENTAL T,MIZRAHI S,KAMYSHNY A,et al. Particle-free compositions for printing dense 3D ceramic structures by digital light processing［J］. Virtual and Physical Prototyping,2021,16(3): 255-266.

[32] ARLT G,HENNINGS D,DE WITH G. Dielectric properties of fine-grained barium titanate ceramics［J］. Journal of Applied Physics,1985,58(4): 1619-1625.

[33] HOSHINA T. Size effect of barium titanate: fine particles and ceramics［J］. Journal of the Ceramic Society of Japan,2013,121(1410): 156-161.

[34] HUAN Y,WANG X H,FANG J,et al. Grain size effect on piezoelectric and ferroelectric properties of BaTiO3 ceramics［J］. Journal of the European Ceramic Society,2014,34(5): 1445-1448.

[35] ZENG T,DONG X L,CHEN S T,et al. Processing and piezoelectric properties of porous PZT ceramics［J］. Ceramics International,2007,33(3): 395-399.