Numerical Study of Current-Induced Domain-Wall Dynamics: Crossover from Spin Transfer to Momentum Transfer

Abstract

We study current-induced dynamics of a magnetic domain wall by solving a time-dependent Schr\"odinger equation combined with Landau-Lifshitz-Gilbert equation in a one-dimensional electron system coupled to localized spins. Two types of domain-wall motions are observed depending on the hard-axis anisotropy, K, of the localized spin system. For small values of K, the magnetic domain wall shows a streaming motion driven by spin transfer. In contrast, for large values of K, a stick-slip motion driven by momentum transfer is obtained. We clarify the origin of these characters of domain-wall motions in terms of the dynamics of one-particle energy levels and distribution functions.