AI Article Synopsis
- Single-molecule magnets have potential for molecular-scale data storage and processing due to their unique magnetization dynamics influenced by electronic and vibrational interactions.
- A non-perturbative vibronic model is developed to analyze low-energy magnetic behaviors, incorporating both electronic and vibrational aspects in monometallic single-molecule magnets.
- The formation of magnetic polarons impacts quantum tunneling of magnetization, reducing its probability by stabilizing low-energy spin states, indicating that spin-phonon coupling plays a significant role in magnetic relaxation even at very low temperatures.
Article Abstract
Single-molecule magnets are among the most promising platforms for achieving molecular-scale data storage and processing. Their magnetisation dynamics are determined by the interplay between electronic and vibrational degrees of freedom, which can couple coherently, leading to complex vibronic dynamics. Building on an ab initio description of the electronic and vibrational Hamiltonians, we formulate a non-perturbative vibronic model of the low-energy magnetic degrees of freedom in monometallic single-molecule magnets. Describing their low-temperature magnetism in terms of magnetic polarons, we are able to quantify the vibronic contribution to the quantum tunnelling of the magnetisation, a process that is commonly assumed to be independent of spin-phonon coupling. We find that the formation of magnetic polarons lowers the tunnelling probability in both amorphous and crystalline systems by stabilising the low-lying spin states. This work, thus, shows that spin-phonon coupling subtly influences magnetic relaxation in single-molecule magnets even at extremely low temperatures where no vibrational excitations are present.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10784566 | PMC |
| http://dx.doi.org/10.1038/s41467-023-44486-3 | DOI Listing |
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