Experimental evidence of multiple magnetic relaxation processes in Mn12 acetate and Mn12 2-Cl benzoate

TL;DR

This study provides experimental evidence of multiple magnetic relaxation processes in Mn12 acetate and Mn12 2-Cl benzoate, revealing a distribution of relaxation times and energy barriers affecting their magnetic quantum tunneling behavior.

Contribution

It demonstrates the existence of a broad distribution of relaxation times and energy barriers, and identifies a second relaxation regime in these Mn12 complexes.

Findings

Presence of a continuous distribution of faster relaxation times.

Effective relaxation times follow an Arrhenius law with specific energy barriers.

Observation of logarithmic relaxation indicating broad energy barrier distribution.

Abstract

The Mn cluster complexes Mn12(RCOO)16(H2O)4O12 with R=CH3 and 2ClPh (hereafter referred to as Mn12 acetate and Mn12 2-Cl benzoate, respectively) exhibit macroscopic magnetic quantum tunneling. Dynamical magnetic measurements indicate for both samples that the anisotropy energy barrier is nearly the same and that the relaxation times have sharp minima at the same resonant fields. However, we show that for both compounds a minority portion of the clusters does not undergo this main relaxation process. From ac-susceptibility experiments, we report evidence of a continuous distribution of faster relaxation times, giving rise to a second relaxation regime. The zero-field effective relaxation times of such a distribution follow an Arrhenius law with energy barrier of approximately 23 and 30 K for the acetate and the benzoate, respectively. In the case of Mn12 2-Cl benzoate, the field dependence of the effective relaxation time points towards the existence of spin tunneling with Hz=0 being a resonant field. The existence of a broad distribution of energy barriers is corroborated in magnetization experiments by the observation of logarithmic relaxation at short times.