Influence of nano-mechanical evolution of Ti <sub>3</sub>AlC <sub>2</sub> ceramic on the arc erosion resistance of Ag-based composite electrical contact material
Xuelian Wu, Chengzhe Wu, Xinpeng Wei, Wanjie Sun, Chengjian Ma, Yundeng Zhang, Gege Li, Liming Chen, Dandan Wang, Peigen Zhang, ZhengMing Sun, Jianxiang Ding
Abstract
Al-containing MAX phase ceramic has demonstrated great potential in the field of high-performance low-voltage electrical contact material. Elucidating the anti-arc erosion mechanism of the MAX phase is crucial for further improving performance, but it is not well-understood. In this study, Ag/Ti<sub>3</sub>AlC<sub>2</sub> electrical contact material was synthesized by powder metallurgy and examined by nanoindentation techniques such as constant loading rate indentation, creep testing, and continuous stiffness measurements. Our results indicated a gradual degradation in the nano-mechanical properties of the Ti<sub>3</sub>AlC<sub>2</sub> reinforcing phase with increasing arc erosion times, although the rate of this degradation appeared to decelerate over arc erosion times. Specifically, continuous stiffness measurements highlighted the uneven mechanical properties within Ti<sub>3</sub>AlC<sub>2</sub>, attributing this heterogeneity to the phase’s decomposition. During the early (1–100 times) and intermediate (100–1000 times) stages of arc erosion, the decline in the nano-mechanical properties of Ti<sub>3</sub>AlC<sub>2</sub> was primarily ascribed to the decomposition of Ti<sub>3</sub>AlC<sub>2</sub> and limited surface oxidation. During the later stage of arc erosion (1000–6200 times), the inner region of Ti<sub>3</sub>AlC<sub>2</sub> also sustained arc damage, but a thick oxide layer formed on its surface, enhancing the mechanical properties and overall arc erosion resistance of the Ag/Ti<sub>3</sub>AlC<sub>2</sub>.