I. Introduction

Anodic activity is pivotal in intense-current vacuum arcs within vacuum circuit breakers (VCBs) [1]–[3]. When vacuum switches are used for capacitive reactive compensation, high-frequency and high-amplitude inrush currents may occur, leading to localized temperature rise on the anode surface due to the plasma of the arcing [4]. According to the IEC back-to-back capacitor switching standard, the high-frequency inrush current has an amplitude of 20 kA and frequency of 4250 Hz [5]. In our previous high-frequency inrush current observation experiment, all the exposure time of the arc is within 2 ms [6]. Therefore, this paper sets the ignition time of the high-frequency inrush current pre-strike arc as 2 ms. The high-temperature action of the arc can lead to the formation of a metal pool on the anode surface. Due to arc pressure, the metal in the pool undergoes deformation and splattering, causing mass loss [7], [8]. Intense anode melting can produce an excessive amount of metal vapor in the VCB at current zero, leading to interruption failures. After arc extinction, the anode surface is left with eroded craters, which intensify the local electric field on the anode surface, making the breaker more susceptible to faults during switching operations [2].