Enhancing rheology and mechanical properties of DLP 3D-printed Si<sub>3</sub>N<sub>4</sub> materials via composition optimization and gas-pressure sintering

Qing Qin; Gang Xiong; Lin Han; Yujuan Zhang; Zhen Shen; Changchun Ge

doi:10.1007/s12613-025-3106-x

International Journal of Minerals, Metallurgy, and Materials ›› 2025 DOI: 10.1007/s12613-025-3106-x

Research Article

Enhancing rheology and mechanical properties of DLP 3D-printed Si₃N₄ materials via composition optimization and gas-pressure sintering

Qing Qin¹ ,
Gang Xiong² ,
Lin Han¹ ,
Yujuan Zhang¹^,^a ,
Zhen Shen²^,^b ,
Changchun Ge¹^,^c

Author information +

History +

Abstract

Digital light processing (DLP) is a crucial additive manufacturing (AM) technique for producing high-precision ceramic components. This study aims to optimize the formulation of Si₃N₄ slurry to enhance both its performance and manufacturability in the DLP process, and investigate key factors such as particle size distribution, photopolymer resin monomer ratios, and dispersant types to improve the slurry’s rheological properties. Through these optimizations, a photosensitive Si₃N₄ slurry with 50vol% solid content was developed, exhibiting excellent stability, and low viscosity (2.48 Pa·s at a shear rate of 12.8 s⁻¹). The effects of gas-pressure sintering on the material’s phase composition, microstructure, and mechanical properties were further explored, revealing that this technique significantly increases the flexural strength of the green sample from (109 ± 10.24) to (618 ± 42.15) MPa. The sintered ceramics exhibited high hardness ((16.59 ± 0.05) GPa) and improved fracture toughness ((4.45 ± 0.03) MPa·m^1/2). Crack trajectory analysis revealed that crack deflection, crack bridging, and the pull-out of rod-like β-Si₃N₄ grains, are the main toughening mechanisms, which could effectively mitigate crack propagation. Among these mechanisms, crack deflection and bridging were particularly influential, significantly enhancing the fracture toughness of the Si₃N₄ matrix. Overall, this research highlights how monomer formulation and gas-pressure sintering strengthen the performance of Si₃N₄ slurry in the DLP three-dimensional printing technique. This work is expected to provide new insights for fabricating complex Si₃N₄ ceramic components with superior mechanical properties.

Keywords

additive manufacturing / Si₃N₄ slurry / low viscosity / pressure sintering / Engineering / Materials Engineering

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Qing Qin, Gang Xiong, Lin Han, Yujuan Zhang, Zhen Shen, Changchun Ge. Enhancing rheology and mechanical properties of DLP 3D-printed Si₃N₄ materials via composition optimization and gas-pressure sintering. International Journal of Minerals, Metallurgy, and Materials, 2025 https://doi.org/10.1007/s12613-025-3106-x

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	TianC, WuJM, WuYR, LiuCL, LinX, ShiYS. Effect of polystyrene addition on properties of porous Si₃N₄ ceramics fabricated by digital light processing. Ceram. Int., 2023, 491627040. CrossRef Google scholar

[2]	M. Li, H.L. Huang, J.M. Wu, et al., Preparation and properties of Si₃N₄ ceramics via digital light processing using Si₃N₄ powder coated with Al₂O₃–Y₂O₃ sintering additives, Addit. Manuf., 53(2022), art. No. 102713.

[3]	S.W. Huang, P. Yang, H.D. Wu, and S.H. Wu, Additive manufacturing of porous silicon nitride inspired by triply periodic minimal surface, 3D Print. Addit. Manuf., (2024): DOI: https://doi.org/10.1089/3dp.2023.0203.

[4]	Y.S. Romario, C. Bhat, M. Ramezani, T. Pasang, Z.W. Chen, and C.P. Jiang, Fabrication of translucent graded dental crown using zirconia-yttrium multi-slurry tape casting 3D printer, J. Mech. Behav. Biomed. Mater., 152(2024), art. No. 106406.

[5]	LiuSY, ChenYJ, LuP, WangBH, ZhangFL, HongJ. Si₃N₄ slurry with high solid phase, low viscosity prepared via surface-oxidation and silane coupling agent modification hybrid method. J. Eur. Ceram. Soc., 2024, 441161. CrossRef Google scholar

[6]	H. Marulcuoglu and F. Kara, Microstructure and mechanical properties of dense Si₃N₄ ceramics prepared by direct coagulation casting and cold isostatic pressing, Mater. Sci. Eng. A, 854(2022), art. No. 143782.

[7]	MillánAJ, NietoMI, MorenoR. Aqueous injection moulding of silicon nitride. J. Eur. Ceram. Soc., 2000, 2014–152661. CrossRef Google scholar

[8]	ZengWM, GanXP, LiZY, ZhouKC. The preparation of silicon nitride ceramics by gelcasting and pressureless sintering. Ceram. Int., 2016, 421011593. CrossRef Google scholar

[9]	HuangZY, LiuLY, YuanJM, et al. . Stereolithography 3D printing of Si₃N₄ cellular ceramics with ultrahigh strength by using highly viscous paste. Ceram. Int., 2023, 4946984. CrossRef Google scholar

[10]	ZhaoDK, BiGJ, ChenJ, et al. . A critical review of direct laser additive manufacturing ceramics. Int. J. Miner. Metall. Mater., 2024, 31122607. CrossRef Google scholar

[11]	ZhangKQ, MengQY, QuZL, HeRJ. A review of defects in vat photopolymerization additive-manufactured ceramics: Characterization, control, and challenges. J. Eur. Ceram. Soc., 2024, 4431361. CrossRef Google scholar

[12]	DongXJ, WuJQ, YuHL, et al. . Additive manufacturing of silicon nitride ceramics: A review of advances and perspectives. Int. J. Appl. Ceram. Technol., 2022, 1962929. CrossRef Google scholar

[13]	ChaudharyR, FabbriP, LeoniE, MazzantiF, AkbariR, AntoniniC. Additive manufacturing by digital light processing: A review. Prog. Addit. Manuf., 2023, 82331. CrossRef Google scholar

[14]	MainesEM, PorwalMK, EllisonCJ, ReinekeTM. Sustainable advances in SLA/DLP 3D printing materials and processes. Green Chem., 2021, 23186863. CrossRef Google scholar

[15]	B. Aktas, R. Das, A. Acikgoz, et al, DLP 3D printing of TiO₂-doped Al₂O₃ bioceramics: Manufacturing, mechanical properties, and biological evaluation, Mater. Today Commun., 38(2024), art. No. 107872.

[16]	GuoJ, ZengY, LiPR, ChenJM. Fine lattice structural titanium dioxide ceramic produced by DLP 3D printing. Ceram. Int., 2019, 451723007. CrossRef Google scholar

[17]	ChenF, ZhuH, WuJM, et al. . Preparation and biological evaluation of ZrO₂ all-ceramic teeth by DLP technology. Ceram. Int., 2020, 46811268. CrossRef Google scholar

[18]	KomissarenkoDA, SokolovPS, EvstigneevaAD, et al. . DLP 3D printing of scandia-stabilized zirconia ceramics. J. Eur. Ceram. Soc., 2021, 411684. CrossRef Google scholar

[19]	WeiSJ, HanGF, ZhangX, et al. . Preparation of high performance dense Al₂O₃ ceramics by digital light processing 3D printing technology. Ceram. Int., 2024, 5012083. CrossRef Google scholar

[20]	A.V.M. Esteves, M.I. Martins, P. Soares, M.A. Rodrigues, M.A. Lopes, and J.D. Santos, Additive manufacturing of ceramic alumina/calcium phosphate structures by DLP 3D printing, Mater. Chem. Phys., 276(2022), art. No. 125417.

[21]	ShenMH, FuRL, LiuHB, et al. . Photosensitive Si₃N₄ slurry with combined benefits of low viscosity and large cured depth for digital light processing 3D printing. J. Eur. Ceram. Soc., 2023, 433881. CrossRef Google scholar

[22]	VargheseG, MoralM, Castro-GarcíaM, et al. . Fabrication and characterisation of ceramics via low-cost DLP 3D printing. Bol. Soc. Esp. Ceram. Vidrio, 2018, 5719. CrossRef Google scholar

[23]	ZouWJ, YangP, LinLF, LiYH, WuSH. Improving cure performance of Si₃N₄ suspension with a high refractive index resin for stereolithography-based additive manufacturing. Ceram. Int., 2022, 48912569. CrossRef Google scholar

[24]	WuXQ, XuCJ, ZhangZM. Development and analysis of a high refractive index liquid phase Si₃N₄ slurry for mask stereolithography. Ceram. Int., 2022, 481120. CrossRef Google scholar

[25]	WuXQ, XuCJ, ZhangZM. Preparation and optimization of Si₃N₄ ceramic slurry for low-cost LCD mask stereolithography. Ceram. Int., 2021, 4779400. CrossRef Google scholar

[26]	HuangRJ, JiangQG, WuHD, et al. . Fabrication of complex shaped ceramic parts with surface-oxidized Si₃N₄ powder via digital light processing based stereolithography method. Ceram. Int., 2019, 4545158. CrossRef Google scholar

[27]	HuangSW, LiYH, YangP, et al. . Cure behaviour and mechanical properties of Si₃N₄ ceramics with bimodal particle size distribution prepared using digital light processing. Ceram. Int., 2023, 49812166. CrossRef Google scholar

[28]	ZhaoJ, ChuW, SongT, et al. . Digital light processing of high-strength Si₃N₄ ceramics: Role of particle grading on slurries curing and mechanical properties. Ceram. Int., 2024, 501322722. CrossRef Google scholar

[29]	HuangJW, LvXA, DongXF, HussainMI, GeCC. Microstructure and mechanical properties of α/β-Si₃N₄ composite ceramics with novel ternary additives prepared via spark plasma sintering. Ceram. Int., 2022, 482030376. CrossRef Google scholar

[30]	DuanWJ, JiaDC, CaiDL, NiuB, YangZH, ZhouY. A facile strategy for fabricating self-sealing dense coating grown in situ on porous silicon nitride ceramics. J. Eur. Ceram. Soc., 2021, 4132162. CrossRef Google scholar

[31]	AswadMA. Comparison of the fracture toughness of high temperature ceramic measured by digital image correlation and indentation method. J. Univ. Babylon Eng. Sci., 2014, 224935

[32]	BürgerR, WendlandWL. Sedimentation and suspension flows: Historical perspectives and some recent developments. J. Eng. Math., 2001, 41: 101. CrossRef Google scholar

[33]	TangJ, GuoXT, ChangHT, et al. . The preparation of SiC ceramic photosensitive slurry for rapid stereolithography. J. Eur. Ceram. Soc., 2021, 41157516. CrossRef Google scholar

[34]	C. Mendes-Felipe, J. Oliveira, I. Etxebarria, J.L. Vilas-Vilela, and S. Lanceros-Mendez, State-of-the-art and future challenges of UV curable polymer-based smart materials for printing technologies, Adv. Mater. Technol., 4(2019), No. 3, art. No. 1800618.

[35]	I. Kim, S. Kim, A. Andreu, J.H. Kim, and Y.J. Yoon, Influence of dispersant concentration toward enhancing printing precision and surface quality of vat photopolymerization 3D printed ceramics, Addit. Manuf., 52(2022), art. No. 102659.

[36]	LiKH, ZhaoZ. The effect of the surfactants on the formulation of UV-curable SLA alumina suspension. Ceram. Int., 2017, 4364761. CrossRef Google scholar

[37]	K. Ruhland, F. Habibollahi, and R. Horny, Quantification and elucidation of the UV-light triggered initiation kinetics of TPO and BAPO in liquid acrylate monomer, J. Appl. Polym. Sci., 137(2020), No. 6, art. No. 48357.

[38]	BagheriA, JinJY. Photopolymerization in 3D printing. ACS Appl. Polym. Mater., 2019, 14593. CrossRef Google scholar

[39]	DingGJ, HeRJ, ZhangKQ, et al. . Stereolithography-based additive manufacturing of gray-colored SiC ceramic green body. J. Am. Ceram. Soc., 2019, 102127198. CrossRef Google scholar

[40]	YangP, SunZF, HuangSW, et al. . Digital light processing 3D printing of surface-oxidized Si₃N₄ coated by silane coupling agent. J. Asian Ceram. Soc., 2022, 10169. CrossRef Google scholar

[41]	X.B. Li, J.X. Zhang, Y.S. Duan, et al., Rheology and curability characterization of photosensitive slurries for 3D printing of Si₃N₄ ceramics, Appl. Sci., 10(2020), No. 18, art. No. 6438.

[42]	HeWC, LüXW, DingCY, YanZM. Oxidation pathway and kinetics of titania slag powders during cooling process in air. Int. J. Miner. Metall. Mater., 2021, 286981. CrossRef Google scholar

[43]	LiuY, ZhanLN, HeY, et al. . Stereolithographical fabrication of dense Si₃N₄ ceramics by slurry optimization and pressure sintering. Ceram. Int., 2020, 4622063. CrossRef Google scholar

[44]	D.L. Lu, K.J. Lin, X.L. He, et al., A synergistic dispersion strategy for high volume fraction slurry and high performance silicon nitride sintered components in digital light processing (DLP)-based vat photopolymerization, Addit. Manuf., 86(2024), art. No. 104182.

[45]	ZuYZ, TangJY, TangCX. Phase transition of α-Si₃N₄ under the condition of high pressure and high temperature. J. Univ. Sci. Technol. Beijing, 2009, 312215

[46]	GandhiAS, LeviCG. Phase selection in precursor-derived yttrium aluminum garnet and related Al₂O₃-Y₂O₃ compositions. J. Mater. Res., 2005, 2041017. CrossRef Google scholar

[47]	HirataT, AkiyamaK, MorimotoT. Synthesis of β-Si₃N₄ particles from α-Si₃N₄ particles. J. Eur. Ceram. Soc., 2000, 2081191. CrossRef Google scholar

[48]	YinS, WanW, FangX, et al. . Mechanical and thermal properties of Si₃N₄ ceramics prepared by gelcasting using high-solid-loading slurries. Ceram. Int., 2023, 492440930. CrossRef Google scholar

[49]	WuYR, TianC, WuJM, et al. . Influence of the ratio of sintering aids on the properties of porous Si₃N₄ ceramics fabricated by digital light processing. Ceram. Int., 2023, 492033004. CrossRef Google scholar

[50]	HuangJW, LvXA, DongXF, RenXN, GeCC. Fabrication of Si₃N₄ ceramics with adjustable microstructure and mechanical properties via Y₂O₃ contents in ZrN–AlN–Y₂O₃ ternary sintering additives. Ceram. Int., 2024, 501324734. CrossRef Google scholar

[51]	WuYR, TianC, WuJM, et al. . Influence of the content of polymethyl methacrylate on the properties of porous Si₃N₄ ceramics fabricated by digital light processing. Ceram. Int., 2023, 491931228. CrossRef Google scholar

[52]	ChenRF, DuanWY, WangG, LiuBS, ZhaoYT, LiS. Preparation of broadband transparent Si₃N₄–SiO₂ ceramics by digital light processing (DLP) 3D printing technology. J. Eur. Ceram. Soc., 2021, 41115495. CrossRef Google scholar

[53]	DongXJ, WuJQ, ZhouQ, et al. . Mechanical and dielectric properties of Si₃N₄–SiO₂ ceramics prepared by digital light processing based 3D printing and oxidation sintering. Ceram. Int., 2023, 491829699. CrossRef Google scholar

[54]	TianC, WangQW, WuJM, et al. . Microstructure and properties of porous Si₃N₄ ceramics fabricated by digital light processing combined with spark plasma sintering. Ceram. Int., 2023, 492440814. CrossRef Google scholar

[55]	WangXY, LiYL, LiuBS, et al. . Preparation of Si₃N₄ ceramic based on digital light processing 3D printing and precursor infiltration and pyrolysis. Int. J. Appl. Ceram. Technol., 2023, 2021017. CrossRef Google scholar

[56]	SunN, WangTP, DuYH, et al. . Effect of TMAH as a modifier on the performance of Si₃N₄ stereolithography pastes. Ceram. Int., 2024, 50915502. CrossRef Google scholar

[57]	ShenMH, FuRL, ZhangY, et al. . Defect-free Si₃N₄ ceramics by vat photopolymerization 3D printing with nitrogen-hydrogen debinding atmosphere. Ceram. Int., 2024, 502142709. CrossRef Google scholar

[58]	WangL, WangLY, HaoZD, TangWZ, DouR. Microstructure and properties of silicon nitride ceramics fabricated by vat photopolymerization in combination with pressureless sintering. Ceram. Int., 2024, 50710485. CrossRef Google scholar