Lanthanides in molecular magnetism: old tools in a new field

Sorace, Lorenzo; Benelli, C.; Gatteschi, Dante

doi:10.1039/c0cs00185f

Cited by 988 publications

(569 citation statements)

References 56 publications

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“…To be more descriptive, the angle between the four-fold axis and the Ln-O bond direction, θ, corresponds to compression or elongation along the tetragonal axis, depending on its value. The magic value for perfect square-antiprismatic (SAP) geometry is θ = 54.74°, while smaller angles correspond to elongation and wider ones lead to compression [38][39][40]. In complex 2, the average value of θ was found to be 56.15°, indicating axial compression.…”

Section: Introductionmentioning

confidence: 94%

Synthesis, Structural, and Magnetic Characterization of a Mixed 3d/4f 12-Metallacrown-4 Family of Complexes

2018

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Section: Introductionmentioning

confidence: 94%

Synthesis, Structural, and Magnetic Characterization of a Mixed 3d/4f 12-Metallacrown-4 Family of Complexes

2018

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“…The SMM behaviour observed for Ln complexes is due to the large magnetic anisotropy of the individual ions, caused by strong spin-orbit coupling and the crystal field (CF) effects due to the ligand environment 13,14 . Other interactions, for example intermolecular effects, often favour efficient quantum tunnelling of magnetization at zero external field, and this factor can mean little magnetic hysteresis is seen even in compounds with very large U eff 13 .…”

mentioning

confidence: 99%

“…Other interactions, for example intermolecular effects, often favour efficient quantum tunnelling of magnetization at zero external field, and this factor can mean little magnetic hysteresis is seen even in compounds with very large U eff 13 . When considering polymetallic Ln complexes, the situation becomes even more complicated.…”

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confidence: 99%

Direct measurement of dysprosium(III)˙˙˙dysprosium(III) interactions in a single-molecule magnet

et al. 2014

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Lanthanide compounds show much higher energy barriers to magnetic relaxation than 3d-block compounds, and this has led to speculation that they could be used in molecular spintronic devices. Prototype molecular spin valves and molecular transistors have been reported, with remarkable experiments showing the influence of nuclear hyperfine coupling on transport properties. Modelling magnetic data measured on lanthanides is always complicated due to the strong spin-orbit coupling and subtle crystal field effects observed for the 4f-ions; this problem becomes still more challenging when interactions between lanthanide ions are also important. Such interactions have been shown to hinder and enhance magnetic relaxation in different examples, hence understanding their nature is vital. Here we are able to measure directly the interaction between two dysprosium(III) ions through multi-frequency electron paramagnetic resonance spectroscopy and other techniques, and explain how this influences the dynamic magnetic behaviour of the system.

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“…The Complete Active Space Self Consistent Field (CASSCF) method can accurately predict the magnetic properties of lanthanide complexes 13,14 , and calculations of this type have become an indispensable tool for the explanation of increasingly interesting magnetic phenomena 6,[15][16][17] . These calculations are especially useful in cases of low symmetry, where previous methods have provided intractable, over parameterized problems 18,19 . Although CASSCF ab initio calculations are extremely versatile and implicitly include all effects required to elucidate the magnetic properties, the results offer little in the way of chemically intuitive explanations and to obtain reliable results requires considerable intervention by expert theorists equipped with access to powerful computational resources.…”

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confidence: 99%

An electrostatic model for the determination of magnetic anisotropy in dysprosium complexes

et al. 2013

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Understanding the anisotropic electronic structure of lanthanide complexes is important in areas as diverse as magnetic resonance imaging, luminescent cell labelling and quantum computing. Here we present an intuitive strategy based on a simple electrostatic method, capable of predicting the magnetic anisotropy of dysprosium(III) complexes, even in low symmetry. The strategy relies only on knowing the X-ray structure of the complex and the well-established observation that, in the absence of high symmetry, the ground state of dysprosium(III) is a doublet quantized along the anisotropy axis with an angular momentum quantum number m J ¼ ± 15 / 2 . The magnetic anisotropy axis of 14 low-symmetry monometallic dysprosium(III) complexes computed via high-level ab initio calculations are very well reproduced by our electrostatic model. Furthermore, we show that the magnetic anisotropy is equally well predicted in a selection of low-symmetry polymetallic complexes.

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Lanthanides in molecular magnetism: old tools in a new field

Cited by 988 publications

References 56 publications

Synthesis, Structural, and Magnetic Characterization of a Mixed 3d/4f 12-Metallacrown-4 Family of Complexes

Synthesis, Structural, and Magnetic Characterization of a Mixed 3d/4f 12-Metallacrown-4 Family of Complexes

Direct measurement of dysprosium(III)˙˙˙dysprosium(III) interactions in a single-molecule magnet

An electrostatic model for the determination of magnetic anisotropy in dysprosium complexes

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