6533b7ddfe1ef96bd1274aba
RESEARCH PRODUCT
Design of high-temperature f-block molecular nanomagnets through the control of vibration-induced spin relaxation
Luis Escalera-morenoAlejandro Gaita-ariñoEugenio CoronadoJosé J. Baldovísubject
Materials science010405 organic chemistryMolecular nanomagnetsAb initioWorking temperatureGeneral ChemistryQuímica010402 general chemistryBlocking (statistics)01 natural sciences0104 chemical sciencesVibrationChemical physicsMagnetSpin relaxationBlock (data storage)description
One of the main roadblocks that still hamper the practical use of molecular nanomagnets is their cryogenic working temperature. In the pursuit of rational strategies to design new molecular nanomagnets with increasing blocking temperature, ab initio methodologies play an important role by guiding synthetic efforts at the lab stage. Nevertheless, when evaluating vibration-induced spin relaxation, these methodologies are still far from being computationally fast enough to provide a useful predictive framework. Herein, we present an inexpensive first-principles method devoted to evaluating vibration-induced spin relaxation in molecular f-block single-ion magnets, with the important advantage of requiring only one CASSCF calculation. The method is illustrated using two case studies based on uranium as the magnetic centre. Finally, we propose chemical modifications in the ligand environment with the aim of suppressing spin relaxation.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-01-01 |