Specific absorption rate of uniaxial single-domain nanomagnets: stochastic spin dynamics versus linear response theory

Abstract

We compute the specific absorption rate of a uniaxial single-domain nanomagnet driven by an alternating magnetic field by two methods: i) direct numerical integration of the stochastic (Langevin) Landau--Lifshitz--Gilbert equation (the LLL approach), and ii) linear response theory (LRT) based on the Debye susceptibility with the Néel relaxation time τN. We first analytically show that both methods are equivalent for small magnetic field amplitude, and then compute their deviation Λ SARLLL/SARLRT-1 as a function of the magnetic field amplitude for two temperatures chosen on opposite sides of the Debye resonance. One of the main results is that the sign and magnitude of Λ are governed by the dimensionless product ωτN, in addition to the linearity parameter ξ=μsB0/kBT for the easy-axis geometry considered here. Indeed, below resonance (ωτN<1), linear response theory overestimates the specific absorption rate. In contrast, above resonance (ωτN>1, the regime typical of blocked nanoparticles), linear response theory can underestimate the specific absorption rate by up to 70\% at ξ2. We expect this work to provide quantitative guidance for the use of linear response theory in magnetic hyperthermia and related nanoscale heat-transport problems, and to serve as a single-particle benchmark for extensions to many-spin and interacting systems.