Three-dimensional printing of Ti3SiC2-based ceramics

Beiya Nan; Xiaowei Yin; Litong Zhang; Laifei Cheng

doi:10.1111/j.1551-2916.2010.04257.x

Three-dimensional printing of Ti₃SiC₂-based ceramics

Beiya Nan, Xiaowei Yin, Litong Zhang, Laifei Cheng

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

88 Scopus citations

Abstract

In the present work, we explored the feasibility of fabricating Ti ₃SiC₂-based ceramics by a near-net-shape fabrication process of three-dimensional printing (3D printing) combined with liquid silicon infiltration (LSI). The porous ceramic preform was fabricated by 3D printing TiC powder with dextrin as a binder. The heat-treated preforms contained bimodal pore structure with interagglomerate pores (dâ23 μm) and intraagglomerate pores (dâ1 μm). Upon infiltration in Ar atmosphere at 1600°-1700°C for 1 h, silicon melt infiltrated the pores and reacted with TiC to yield Ti₃SiC₂, TiSi_2, and SiC. The effects of silicon content and infiltration temperature on the phase composition of the Ti₃SiC₂-based composites were also studied. After LSI at 1700°C for 1 h, the composites with an initial TiC:Si mole ratio of 3:1.2 attained a bending strength of 293 MPa, a Vickers hardness of 7.2 GPa, and an electrical resistivity of 27.8 μÎ

Original language	English
Pages (from-to)	969-972
Number of pages	4
Journal	Journal of the American Ceramic Society
Volume	94
Issue number	4
DOIs	https://doi.org/10.1111/j.1551-2916.2010.04257.x
State	Published - Apr 2011

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title = "Three-dimensional printing of Ti3SiC2-based ceramics",

abstract = "In the present work, we explored the feasibility of fabricating Ti 3SiC2-based ceramics by a near-net-shape fabrication process of three-dimensional printing (3D printing) combined with liquid silicon infiltration (LSI). The porous ceramic preform was fabricated by 3D printing TiC powder with dextrin as a binder. The heat-treated preforms contained bimodal pore structure with interagglomerate pores (d{\^a}23 μm) and intraagglomerate pores (d{\^a}1 μm). Upon infiltration in Ar atmosphere at 1600°-1700°C for 1 h, silicon melt infiltrated the pores and reacted with TiC to yield Ti3SiC2, TiSi2, and SiC. The effects of silicon content and infiltration temperature on the phase composition of the Ti3SiC2-based composites were also studied. After LSI at 1700°C for 1 h, the composites with an initial TiC:Si mole ratio of 3:1.2 attained a bending strength of 293 MPa, a Vickers hardness of 7.2 GPa, and an electrical resistivity of 27.8 μ{\^I}",

author = "Beiya Nan and Xiaowei Yin and Litong Zhang and Laifei Cheng",

year = "2011",

month = apr,

doi = "10.1111/j.1551-2916.2010.04257.x",

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volume = "94",

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T1 - Three-dimensional printing of Ti3SiC2-based ceramics

AU - Nan, Beiya

AU - Yin, Xiaowei

AU - Zhang, Litong

AU - Cheng, Laifei

PY - 2011/4

Y1 - 2011/4

N2 - In the present work, we explored the feasibility of fabricating Ti 3SiC2-based ceramics by a near-net-shape fabrication process of three-dimensional printing (3D printing) combined with liquid silicon infiltration (LSI). The porous ceramic preform was fabricated by 3D printing TiC powder with dextrin as a binder. The heat-treated preforms contained bimodal pore structure with interagglomerate pores (dâ23 μm) and intraagglomerate pores (dâ1 μm). Upon infiltration in Ar atmosphere at 1600°-1700°C for 1 h, silicon melt infiltrated the pores and reacted with TiC to yield Ti3SiC2, TiSi2, and SiC. The effects of silicon content and infiltration temperature on the phase composition of the Ti3SiC2-based composites were also studied. After LSI at 1700°C for 1 h, the composites with an initial TiC:Si mole ratio of 3:1.2 attained a bending strength of 293 MPa, a Vickers hardness of 7.2 GPa, and an electrical resistivity of 27.8 μÎ

AB - In the present work, we explored the feasibility of fabricating Ti 3SiC2-based ceramics by a near-net-shape fabrication process of three-dimensional printing (3D printing) combined with liquid silicon infiltration (LSI). The porous ceramic preform was fabricated by 3D printing TiC powder with dextrin as a binder. The heat-treated preforms contained bimodal pore structure with interagglomerate pores (dâ23 μm) and intraagglomerate pores (dâ1 μm). Upon infiltration in Ar atmosphere at 1600°-1700°C for 1 h, silicon melt infiltrated the pores and reacted with TiC to yield Ti3SiC2, TiSi2, and SiC. The effects of silicon content and infiltration temperature on the phase composition of the Ti3SiC2-based composites were also studied. After LSI at 1700°C for 1 h, the composites with an initial TiC:Si mole ratio of 3:1.2 attained a bending strength of 293 MPa, a Vickers hardness of 7.2 GPa, and an electrical resistivity of 27.8 μÎ

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ER -

Three-dimensional printing of Ti₃SiC₂-based ceramics

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