Investigation on the arc erosion performance of Ag–Ta <sub>2</sub>AlC composite under air conditions
Xiaochen Huang, Liang Li, Jinlong Ge, Hao Zhao, Zijue Zhou
Abstract
The Ta<sub>2</sub>AlC material is designed to enhance the performance of Ag-based electrical contact materials as a reinforcement phase. With a work function of 6.7192 eV, Ta<sub>2</sub>AlC demonstrated significantly higher values compared to reinforcement phase materials such as SnO<sub>2</sub>, ZrO<sub>2</sub>, and the commonly used MAX phase materials. Consequently, the arc erosion performance of an Ag-Ta<sub>2</sub>AlC composite was investigated under air conditions. Gas breakdown mainly occurred due to electron avalanche, with the observation of streamer breakdown mechanism in a strongly nonuniform field. The arc exhibited concentrated erosion on the surface of Ag-20 vol.% Ta<sub>2</sub>AlC material, resulting in higher arc energy. As the volume fractions of Ta<sub>2</sub>AlC material increased to 30% and 40%, the eroded area became more dispersed. Particularly, Ag-30 vol.% Ta<sub>2</sub>AlC displayed the lowest arc energy (3.395 kJ) and shortest arcing time (33.26 ms). Among the four components, Ag-30 vol.% Ta<sub>2</sub>AlC composite demonstrated superior arc erosion resistance. The oxides of Ag<sub>2</sub>O, AgO, Ta<sub>2</sub>O<sub>5</sub>, and Al<sub>2</sub>O<sub>3</sub> were formed through the interaction of ionized Ag and Ta<sub>2</sub>AlC particles. By the combination of electromagnetic force and plasma flow force, sputtered particles and bulges were generated on the eroded surface. These research findings contribute to broadening the application of Ag-MAX materials in the realm of electrical contacts.