Mechanism of Lowering the Sintering Temperature of Al2O3 Ceramic by the Addition of CuO–TiO2 (II)

Chin J Mater Res

2010, Vol. 24

Issue (1): 37-43 DOI:

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Mechanism of Lowering the Sintering Temperature of Al₂O₃ Ceramic by the Addition of CuO–TiO₂ (II)

WANG Huanping¹; ZHANG Bin¹; MA Hongping²; XU Shiqing¹; LI Denghao¹; ZHOU Guangmiao¹

1.College of Materials Science and Engineering; China Jiliang University; Hangzhou 310018
2.School of Mechanical & Automotive Engineering; Zhejiang University of Science and Technology; Hangzhou 310012

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WANG Huanping ZHANG Bin MA Hongping XU Shiqing LI Denghao ZHOU Guangmiao. Mechanism of Lowering the Sintering Temperature of Al₂O₃ Ceramic by the Addition of CuO–TiO₂ (II). Chin J Mater Res, 2010, 24(1): 37-43.

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Abstract

The effects of CuO and TiO₂ additives on the sintering behavior, microstructure, phase composition, sintering activation energy and the mechanism of lowering the sintering temperature of Al₂O₃ ceramics have been investigated. The TiO₂ began to dissolve into Al₂O₃and formed Al₂Ti₇O₁₅solid solution at the sintering temperature of 1150–1200^oC , and the diffusion coefficient improved largely with the augment of Al ³⁺ vacancy concentration, which was the essential reason why the sintering process of A1₂O₃ ceramic had been promoted by the TiO₂ addition. However, the solid solubility limit of TiO₂ was 2%–4% (mass fraction), and it was unuseful for lowering the sintering temperature of A1₂O₃ ceramic by doping superfluous TiO₂. The temperature of TiO₂dissolved into Al₂O₃ could be lowed down to 1100 with the addition of 0.4% CuO, which was effective to promote the sintering process of A1₂O₃ ceramic. The sintering activation energy of alumina ceramic doped with different CuO–TiO₂was consistent with the above results. The sintering activation energy of A1₂O₃ ceramic was reduced to 54.15 kJ·mol⁻¹ by adding 4% TiO₂and 2.4% CuO.

Key words: inorganic non-metallic materials Al₂O₃ sintering additive liquid phase sintering solid-state reaction sintering

Received: 30 July 2009

Fund:

Supported by the Program for New Century Excellent Talents in University No.NCET–07–0786, and the
Science Technology of Zhejiang Province No.2008C21053/2008C21054.

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https://www.cjmr.org/EN/ OR https://www.cjmr.org/EN/Y2010/V24/I1/37

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