What Controls the Sign and Magnitude of Magnetic Anisotropy in Tetrahedral Cobalt(II) Single-Ion Magnets?

Vaidya, S.; Tewary, Subrata; Singh, Saurabh Kumar; Langley, Stuart K.; Murray, Keith S.; Lan, Yanhua; Wernsdorfer, Wolfgang; Rajaraman, Gopalan; Shanmugam, Maheswaran

doi:10.1021/acs.inorgchem.6b01073

Cited by 104 publications

(112 citation statements)

References 91 publications

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“…Most robust complexes based on Co II belong to four coordinate tetrahedral geometries where various means are proposing to fine tune both the sign and magnitude of the zero‐field splitting parameter. While {CoS 4 } remains one of the thoroughly studied systems and exhibit U eff values as large as 62 cm −1 , how the magnitude and the sign of D values vary if mixed donor ligands are employed has not been explored in detail.…”

Section: Introductionmentioning

confidence: 99%

“…Ab initio calculations are proven to a powerful tool in this area wherein methodology based on multi‐reference CASSCF/NEVPT2 methods have been utilized to compute zero‐field splitting parameters of various transition metal SIMs successfully . Particularly in tetrahedral Co II complexes, this methodology has been used to even predict suitable target molecules possessing very large negative D values . Here in this manuscript, we attempt to undertake a theoretical study based on ab initio CASSCF methods to understand and predict the anisotropy in twelve Co II complexes containing [CoX 4 ] (X=O, S and Se) cores which are reported in the literature.…”

Section: Introductionmentioning

confidence: 99%

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Magnetic Anisotropy in Co^IIX₄ (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect

Sarkar

Tewary

Sinkar

et al. 2019

Chemistry An Asian Journal

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Mononuclearf our coordinate Co II complexes have drawn ag reat deal of attention as they often exhibit excellent single-ion magnet (SIM) properties. Among the reported complexes, the axial zero-field splitting parameter (D)w as found to vary drastically both in terms of the sign as well as strength. There are variousp roposals in this respects uch as structural distortions,h eaviera tom substitution, metalligand covalency,t uning secondary coordination sphere, etc. that are expected to control the D values. To assess the importance of structurald istortions vs. heaviera tom substitution effect, herew eh ave undertaken detailed theoretical studies based on the ab initio CASSCF/NEVPT2 methodt o estimate zero-field splitting parameters for twelve complexes reported in the literature. Our test set includes the {Co II X 4 } (where X = O, S, Se) core structure where the D value was found to vary from + 19 to À118cm À1 .B ased on the structural variation, we have classified the complexes into three types (I-III)w here type I complexes were found to exhibit the largestn egative D value as desired for SIMs. The other two types (II and III)o fc omplexes have been found to be inferior with respect to type I. The secondary coordination spherew as also found to influence D,a ss ubstitution on the secondary coordination sphere atom was found to significantly alter the magnitude of D values. Particularly,t wo structuralp arameters, namely,t he dihedrala ngle between the two ligand planes and the ffX-Co-X polar angle were found to heavily influence the sign and strength of D values. Our analysis clearly reveals that these structural factors are much more important than the heavier atom substitution,o r metal-ligand covalency.Alarge variation in the D and E/D values among these complexesd espite possessing av ery close structuralsimilarity offers an exquisite playground for a chemistt odesign and develop new-generation Co II -based SIMs.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Magnetic Anisotropy in Co^IIX₄ (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect

Sarkar

Tewary

Sinkar

et al. 2019

Chemistry An Asian Journal

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“…[6][7][8] Complexes that contain only one metal centerm ay represent the smallestc hemically tuneableS MMs for spin-based devices, [9] and significant progress has been made in this regard by using lanthanides [3,10] and, more recently,3 dm etal ions. However,f ew examples of zero-field SMMs based on mononuclear complexes of iron(I) [12] iron(III), [13] and cobalt(II) have been reported, [14][15][16][17][18][19][20][21][22][23][24][25] which all feature half-integer spin states (S = 3/2 or 5/2). However,f ew examples of zero-field SMMs based on mononuclear complexes of iron(I) [12] iron(III), [13] and cobalt(II) have been reported, [14][15][16][17][18][19][20][21][22][23][24][25] which all feature half-integer spin states (S = 3/2 or 5/2).…”

Section: Introductionmentioning

confidence: 99%

A Pseudo‐Octahedral Cobalt(II) Complex with Bispyrazolylpyridine Ligands Acting as a Zero‐Field Single‐Molecule Magnet with Easy Axis Anisotropy

Rigamonti

Bridonneau

Poneti

et al. 2018

Chemistry A European J

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The homoleptic mononuclear compound [Co(bpp-COOMe) ](ClO ) (1) (bpp-COOMe=methyl 2,6-di(pyrazol-1-yl)pyridine-4-carboxylate) crystallizes in the monoclinic C2/c space group, and the cobalt(II) ion possesses a pseudo-octahedral environment given by the two mer-coordinated tridentate ligands. Direct-current magnetic data, single-crystal torque magnetometry, and EPR measurements disclosed the easy-axis nature of this cobalt(II) complex, which shows single-molecule magnet behavior when a static field is applied in alternating-current susceptibility measurements. Diamagnetic dilution in the zinc(II) analogue [Zn(bpp-COOMe) ](ClO ) (2) afforded the derivative [Zn Co (bpp-COOMe) ](ClO ) (3), which exhibits slow relaxation of magnetization even in zero field thanks to the reduction of dipolar interactions. Theoretical calculations confirmed the overall electronic structure and the magnetic scenario of the compound as drawn by experimental data, thus confirming the spin-phonon Raman relaxation mechanism, and a direct quantum tunneling in the ground state as the most plausible relaxation pathway in zero field.

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“…[9,10,[20][21][22][23][24][25][26][27][28] Die Hysteresekurve weist eine markante Taillierung auf und die Koerzitivfeldstärke ist relativ klein, was auf signifikantes Quantentunneln hinweist. Diese Messungen ergaben eine ausgeprägte Hysterese mit einer Breite von einigen Te sla bei Te mperaturen bis 15 K, was ungewçhnlich fürC obalt-Einzelmolekülmagnete ist.…”

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“…Diese Messungen ergaben eine ausgeprägte Hysterese mit einer Breite von einigen Te sla bei Te mperaturen bis 15 K, was ungewçhnlich fürC obalt-Einzelmolekülmagnete ist. [27] Mangan(III) weist interessanterweise ähnliche Werte fürd ie Hyperfeinkopplung auf, [30] aber die auf Mangan(III) basierenden Einzelmolekülmagneten neigen nicht zu einer durch Hyperfeinkopplung verursachten Relaxation. Aufgrund der ungeraden Anzahl an ungepaarten Elektronen ist Komplex 2 ein Kramers-System, was bedeutet, dass Tu nneln nicht durch rhombische Nullfeldaufspaltung verursacht wird.…”

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Drastische Verlangsamung der magnetischen Relaxation durch starke Austauschkopplungen in einem luftstabilen, radikalverbrückten Cobalt(II)‐Einzelmolekülmagneten

et al. 2019

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Die zur magnetischen Bistabilitätf ührende Energiebarriere wird in molekularen Clustern durch die magnetische Anisotropie der einzelnen Komponenten des Clusters bestimmt. Die Verwendung eines anisotropen, vierfachk oordinierten Cobalt(II)-Bausteines ermçglichte die Darstellung eines luft-und hydrolysestabilen, stark gekoppelten Drei-Spin-Systems.D ieses konnte den Raman-Relaxationsprozess erheblich unterdrücken, wodurchd ie Relaxation der Magnetisierung gegenüber der des verwendeten Bausteins um ein 350faches verlängert wurde,mit dem gleichzeitigen Auftreten einer ausgeprägten Hysterese.B ei niedrigen Temperaturen konnte somit eine Relaxationszeit von bis zu 9Stunden beobachtet werden.

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What Controls the Sign and Magnitude of Magnetic Anisotropy in Tetrahedral Cobalt(II) Single-Ion Magnets?

Cited by 104 publications

References 91 publications

Magnetic Anisotropy in Co^IIX₄ (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect

Magnetic Anisotropy in Co^IIX₄ (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect

A Pseudo‐Octahedral Cobalt(II) Complex with Bispyrazolylpyridine Ligands Acting as a Zero‐Field Single‐Molecule Magnet with Easy Axis Anisotropy

Drastische Verlangsamung der magnetischen Relaxation durch starke Austauschkopplungen in einem luftstabilen, radikalverbrückten Cobalt(II)‐Einzelmolekülmagneten

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What Controls the Sign and Magnitude of Magnetic Anisotropy in Tetrahedral Cobalt(II) Single-Ion Magnets?

Cited by 104 publications

References 91 publications

Magnetic Anisotropy in CoIIX4 (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect

Magnetic Anisotropy in CoIIX4 (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect

A Pseudo‐Octahedral Cobalt(II) Complex with Bispyrazolylpyridine Ligands Acting as a Zero‐Field Single‐Molecule Magnet with Easy Axis Anisotropy

Drastische Verlangsamung der magnetischen Relaxation durch starke Austauschkopplungen in einem luftstabilen, radikalverbrückten Cobalt(II)‐Einzelmolekülmagneten

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Magnetic Anisotropy in Co^IIX₄ (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect

Magnetic Anisotropy in Co^IIX₄ (X=O, S, Se) Single‐Ion Magnets: Role of Structural Distortions versus Heavy Atom Effect