Magnetic domain structure and domain-wall bound states of the topological semimetal EuB6

Electrically manipulating domain wall (DW) is central in the field of spintronics. Magnetic Weyl semimetal (WSM) offers an additional knob for electric manipulation of DW by utilizing the topological DW bound states. Using magnetic WSM material EuB6 as a prototype system, we investigate its DW bound states combining first -principles calculations and domain imaging via magnetic force microscopy (MFM). The MFM measurements reveal that domains with magnetization aligned along three [100] directions dominate over others under a small magnetic field along the [001] direction. Accordingly, first-principles calculations are performed based on experimentally determined DW type, which show a robust DW bound state featuring a spectral distribution over a large portion of the DW Brillouin zone. Such DW bound states should result in a significant amount of localized charges which can be used to drive DW motion via the electrostatic forces exerted on the localized DW charges.