# Spin-lattice relaxation of magnetic centers in molecular crystals at low   temperature

**Authors:** Le Tuan Anh Ho, Liviu F. Chibotaru

arXiv: 1704.06699 · 2018-01-31

## TL;DR

This paper derives universal, measurable formulae for spin-phonon relaxation rates in molecular magnets at low temperature, revealing dependencies on magnetic field orientation and temperature, and proposes strategies for improving single-molecule magnet performance.

## Contribution

The paper introduces universal, measurable formulae for spin-phonon relaxation rates that are independent of excited state energy gaps, applicable to both Kramers and non-Kramers systems.

## Key findings

- Relaxation rates expressed via measurable quantities
- Raman process depends on magnetic field orientation
- Raman process varies as T^9 in both systems

## Abstract

We study the spin-phonon relaxation rate of both Kramers and non-Kramers molecular magnets in strongly diluted samples at low temperature. Using the "rotational" contribution to the spin-phonon Hamiltonian, universal formulae for the relaxation rate are obtained. Intriguingly, these formulae are all entirely expressed via measurable or \emph{ab initio} computable physical quantities. Moreover, they are also independent of the energy gaps to excited states involved in the relaxation process. These obtained expressions for direct and Raman processes offer an easy way to determine the lowest limit of the spin-phonon relaxation of any spin system based on magnetic properties of the ground doublet only. In addition, some intriguing properties of Raman process are also found. Particularly, Raman process in Kramers system is found dependent on the magnetic field's orientation but independent of its magnitude, meanwhile the same process in non-Kramers system is significantly reduced out of resonance, i.e. for an applied external field. Interestingly, Raman process is demonstrated to vary as $T^{9}$ for both systems. Application of the theory to a recently investigated cobalt(II) complex shows that it can provide a reasonably good description for the relaxation. Based on these findings, a strategy in developing efficient single-molecule magnets by enhancing the mechanical rigidity of the molecular unit is proposed.

## Full text

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## Figures

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## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1704.06699/full.md

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Source: https://tomesphere.com/paper/1704.06699