Abstract
Spin–phonon coupling plays an important role in single-molecule magnets and molecular qubits. However, there have been few detailed studies of its nature. Here, we show for the first time distinct couplings of g phonons of CoII(acac)2(H2O)2 (acac = acetylacetonate) and its deuterated analogs with zero-field-split, excited magnetic/spin levels (Kramers doublet (KD)) of the S = 3/2 electronic ground state. The couplings are observed as avoided crossings in magnetic-field-dependent Raman spectra with coupling constants of 1–2 cm−1. Far-IR spectra reveal the magnetic-dipole-allowed, inter-KD transition, shifting to higher energy with increasing field. Density functional theory calculations are used to rationalize energies and symmetries of the phonons. A vibronic coupling model, supported by electronic structure calculations, is proposed to rationalize the behavior of the coupled Raman peaks. This work spectroscopically reveals and quantitates the spin–phonon couplings in typical transition metal complexes and sheds light on the origin of the spin–phonon entanglement.
Highlights
Spin–phonon coupling plays an important role in single-molecule magnets and molecular qubits
Transition metal complexes displaying slow magnetic relaxation are of great interest for possible use as singlemolecule magnets (SMMs) and qubits[1,2,3,4,5,6,7,8,9,10]
Recent experimental evidence in this area includes work performed by Rechkemmer and coworkers to observe spin–phonon couplings of two field-dependent absorptions of a CoII SMM with far-IR spectroscopy[22]
Summary
Spin–phonon coupling plays an important role in single-molecule magnets and molecular qubits. The interKramers transition moves and interacts with other phonons of g symmetry, rendering avoided crossings (coupling constants ≈ 1–2 cm−1). In Raman spectroscopy, phonon features of the coupled peaks are observed with applied magnetic fields.
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