Domain wall motion in axially symmetric spintronic nanowires

TL;DR

This paper investigates the stability and dynamics of magnetic domain walls in axially symmetric spintronic nanowires using analytical and numerical methods, revealing stability regimes, selection mechanisms, and explicit formulas for spectral properties.

Contribution

It provides new analytical formulas for stability spectra and elucidates the selection mechanisms of domain wall velocity and frequency in spintronic nanowires.

Findings

Identified bistable and monostable parameter regimes for domain wall stability.

Derived explicit formulas for the absolute spectrum of the linearized operator.

Confirmed the linear selection mechanism through long-time numerical simulations.

Abstract

This article is concerned with the dynamics of magnetic domain walls (DWs) in nanowires as solutions to the classical Landau-Lifschitz-Gilbert equation augmented by a typically non-variational Slonczewski term for spin-torque effects. Taking applied field and spin-polarization as the primary parameters, we study dynamic stability as well as selection mechanisms analytically and numerically in an axially symmetric setting. Concerning the stability of the DWs' asymptotic states, we distinguish the bistable (both stable) and the monostable (one unstable, one stable) parameter regime. In the bistable regime, we extend known stability results of an explicit family of precessing solutions and identify a relation of applied field and spin-polarization for standing DWs. We verify that this family is convectively unstable into the monostable regime, thus forming so-called pushed fronts, before turning absolutely unstable. In the monostable regime, we present explicit formulas for the so-called absolute spectrum of more general matrix operators. This allows us to relate translation and rotation symmetries to the position of the singularities of the pointwise Green's function. Thereby, we determine the linear selection mechanism for the asymptotic velocity and frequency of DWs and corroborate these by long-time numerical simulations. All these results include the axially symmetric Landau-Lifschitz-Gilbert equation.