Skyrmion Lattices in Electric Fields

This paper studies the influence of electric fields on the skyrmion lattice (SkL) in insulating skyrmion compounds with weak magnetoelectric (ME) coupling. The ME coupling mechanism is an interaction between the external electric field $E$ and local magnetization in the sample. Physically, the $E$-field perturbs the spin modulation wave vectors resulting in the distortion of the SkL and the $E$-field induced shift in energy. Due to the relativistic smallness of ME coupling, the important physics is captured already in the elastic ($\propto$$E$) and inelastic ($\propto$$E^2$) responses. In this spirit, the effect of the fourth-order cubic anisotropy responsible for stabilization of the skyrmion phase is taken into account perturbatively. The shift in energy can be either positive or negative, -- depending on the direction of electric field, -- thus stabilizing or destabilizing the SkL phase. Understanding the $E$-field energetics is important from the viewpoint of creation (writing) and destruction (erasing) of skyrmion arrays over the bulk, which is paramount for developing skyrmion-based logical elements and data storage.