Magnetic Quantum Tunneling: Insights from Simple Molecule-Based Magnets

TL;DR

This paper provides a comprehensive analysis of magnetic quantum tunneling in simple, low-nuclearity single-molecule magnets, combining experimental data and theoretical calculations to understand the factors influencing quantum dynamics.

Contribution

It systematically studies how individual-ion anisotropies affect the molecular spin ground state and quantum tunneling in simple transition metal clusters, supported by extensive experimental data.

Findings

Projection of single-ion anisotropies onto the molecular ground state influences tunneling.

High symmetry and low disorder in molecules are crucial for understanding quantum tunneling.

Numerical diagonalization reveals interplay between exchange interactions and anisotropy.

Abstract

This article takes a broad view of the understanding of magnetic bistability and magnetic quantum tunneling in single-molecule magnets (SMMs), focusing on three families of relatively simple, low-nuclearity transition metal clusters: spin S = 4 Ni4, Mn(III)3 (S = 2 and 6) and Mn(III)6 (S = 4 and 12). The Mn(III) complexes are related by the fact that they contain triangular Mn3 units in which the exchange may be switched from antiferromagnetic to ferromagnetic without significantly altering the coordination around the Mn(III) centers, thereby leaving the single-ion physics more-or-less unaltered. This allows for a detailed and systematic study of the way in which the individual-ion anisotropies project onto the molecular spin ground state in otherwise identical low- and high-spin molecules, thus providing unique insights into the key factors that control the quantum dynamics of SMMs, namely: (i) the height of the kinetic barrier to magnetization relaxation; and (ii) the transverse interactions that cause tunneling through this barrier. Numerical calculations are supported by an unprecedented experimental data set (17 different compounds), including very detailed spectroscopic information obtained from high-frequency electron paramagnetic resonance and low-temperature hysteresis measurements. Diagonalization of the multi-spin Hamiltonian matrix is necessary in order to fully capture the interplay between exchange and local anisotropy, and the resultant spin-state mixing which ultimately gives rise to the tunneling matrix elements in the high symmetry SMMs (ferromagnetic Mn3 and Ni4). The simplicity (low-nuclearity, high-symmetry, weak disorder, etc..) of the molecules highlighted in this study proves to be of crucial importance.