Spark plasma sintering of TiC with TiAly as sintering aid: Mechanisms and microstructures

IF 2.9 Q1 MATERIALS SCIENCE, CERAMICS Open Ceramics Pub Date : 2024-09-01 DOI:10.1016/j.oceram.2024.100661

Alessandro Rizzi , María García-Fernández , Miguel Á. Rodríguez , Emanuele De Bona , Rodrigo Moreno , Mattia Biesuz

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Abstract

TiC features an interesting combination of mechanical properties, high-temperature resistance, and lightness, making it an excellent candidate for several applications in harsh environments. However, its sintering to obtain bulk components is extremely challenging. Herein, we show that titanium aluminide is a promising sintering aid for TiC (5, 10, and 20 vol% were investigated). The aluminide allows the formation of a nearly fully dense component at 1350 °C by spark plasma sintering under 80 MPa. The aluminide forms a grain boundary secondary phase that promotes the Ti diffusion: Ti from TiC can be dissolved within the TiAl_y at the neck center and precipitate at the neck surface, while C can easily diffuse through the TiC lattice. Higher temperatures cause the extrusion of the aluminide out of the SPS die and its reaction with oxygen impurities. The final microstructure is constituted by nearly pure TiC with isolated alumina pockets at the triple points.

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以 TiAly 为烧结助剂的火花等离子烧结 TiC：机理和微结构

TiC 集机械性能、耐高温性和轻质于一身，是恶劣环境中多种应用的理想选择。然而，通过烧结获得块状元件却极具挑战性。在本文中，我们发现钛铝化物是一种很有前景的钛碳烧结助剂（研究对象为 5、10 和 20 Vol%）。通过在 80 兆帕下进行火花等离子烧结，铝化钛可在 1350 摄氏度时形成近乎完全致密的成分。铝化物形成的晶界次生相促进了钛的扩散：TiC 中的 Ti 可以溶解在颈部中心的 TiAly 中，并在颈部表面析出，而 C 则很容易通过 TiC 晶格扩散。温度升高会导致铝化物从 SPS 模具中挤出，并与氧杂质发生反应。最终的微观结构由几乎纯净的 TiC 构成，在三点处有孤立的氧化铝袋。

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