Longitudinal relaxation and thermoactivation of quantum superparamagnets

TL;DR

This paper analyzes the relaxation mechanisms of quantum nanomagnets using linear response theory, identifying thermal activation and intra-well dynamics, and provides analytical formulas that match numerical results across various conditions.

Contribution

It introduces a simple analytical formula for quantum superparamagnet relaxation that accounts for thermal activation and intra-well dynamics, extending classical results to quantum cases.

Findings

Analytical formula agrees with numerical results.

Identifies two main relaxation mechanisms.

Generalizes classical results to quantum superparamagnets.

Abstract

The relaxation mechanisms of a quantum nanomagnet are discussed in the frame of linear response theory. We use a spin Hamiltonian with a uniaxial potential barrier plus a Zeeman term. The spin, having arbitrary $S$, is coupled to a bosonic environment. From the eigenstructure of the relaxation matrix, we identify two main mechanisms, namely, thermal activation over the barrier, with a time scale $\eival_1^{-1}$, and a faster dynamics inside the potential wells, with characteristic time $\eivalW^{-1}$. This allows to introduce a simple analytical formula for the response, which agrees well with the exact numerical results, and cover experiments even under moderate to strong fields in the superparamagnetic range. In passing, we generalize known classical results for a number of quantities (e.g., integral relaxation times, initial decay time, Kramers rate), results that are recovered in the limit $S\to\infty$.