Lanthanide-based single-molecule magnets (SMMs) are promising
building
blocks for quantum memory and spintronic devices. Designing lanthanide-based
SMMs with long spin relaxation time requires a detailed understanding
of their electronic structure, including the crucial role of the spin–orbit
coupling (SOC). While traditional calculations of SOC using the perturbation
theory applied to a solution of the nonrelativistic Schrödinger
equation are valid for light atoms, this approach is questionable
for systems containing heavy elements such as lanthanides. We investigate
the accuracy of the perturbation estimates of SOC by variationally
solving the Dirac equation for the [DyO]+ molecule, a prototype
of a lanthanide-based SMM. We show that the energy splittings between
the
states involved in spin relaxation depend
on the interplay between strong SOC and dynamic electron correlation.
We demonstrate that this interplay affects the resonances between
the spin and vibrational transitions and, therefore, the spin relaxation
time.
The synthesis and magnetic properties of two pairs of isomeric, exchange-coupled complexes, [LnCl6(TiCp2)3] (Ln = Gd, Tb), are reported. In each isomeric pair, the central lanthanide ion adopts either a...
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