Vanadium(iv) complexes have recently shown record quantum spin coherence times that in several circumstances are limited by spin-lattice relaxation. The role of the environment and vibronic properties in the low temperature dynamics is here investigated by a comparative study of the magnetization dynamics as a function of crystallite size and the steric hindrance of the β-diketonate ligands in VO(acac)2 (1), VO(dpm)2 (2) and VO(dbm)2 (3) evaporable complexes (acac(-) = acetylacetonate, dpm(-) = dipivaloylmethanate, and dbm(-) = dibenzoylmethanate). A pronounced crystallite size dependence of the relaxation time is observed at unusually high temperatures (up to 40 K), which is associated with a giant spin-phonon bottleneck effect. We model this behaviour by an ad hoc force field approach derived from density functional theory calculations, which evidences a correlation of the intensity of the phenomenon with ligand dimensions and the unit cell size.
Giant spin-phonon bottleneck effects in evaporable vanadyl-based molecules with long spin coherence / Tesi, L; Lunghi, A; Atzori, M; Lucaccini, E; Sorace, L; Totti, F; Sessoli, R. - In: DALTON TRANSACTIONS. - ISSN 1477-9234. - ELETTRONICO. - 45:(2016), pp. 16635-16643. [10.1039/c6dt02559e]
Giant spin-phonon bottleneck effects in evaporable vanadyl-based molecules with long spin coherence
TESI, LORENZO;LUNGHI, ALESSANDRO;ATZORI, MATTEO;LUCACCINI, EVA;SORACE, LORENZO;TOTTI, FEDERICO;SESSOLI, ROBERTA
2016
Abstract
Vanadium(iv) complexes have recently shown record quantum spin coherence times that in several circumstances are limited by spin-lattice relaxation. The role of the environment and vibronic properties in the low temperature dynamics is here investigated by a comparative study of the magnetization dynamics as a function of crystallite size and the steric hindrance of the β-diketonate ligands in VO(acac)2 (1), VO(dpm)2 (2) and VO(dbm)2 (3) evaporable complexes (acac(-) = acetylacetonate, dpm(-) = dipivaloylmethanate, and dbm(-) = dibenzoylmethanate). A pronounced crystallite size dependence of the relaxation time is observed at unusually high temperatures (up to 40 K), which is associated with a giant spin-phonon bottleneck effect. We model this behaviour by an ad hoc force field approach derived from density functional theory calculations, which evidences a correlation of the intensity of the phenomenon with ligand dimensions and the unit cell size.File | Dimensione | Formato | |
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