Two-Coordinate Co(II) Imido Complexes as Outstanding Single-Molecule Magnets

Yao, Xiao-Nan; Du, Jingzhen; Zhang, Yi‐Quan; Leng, Xuebing; Yang, Muwen; Jiang, Shang‐Da; Wang, Zhenxing; Ouyang, Zhongwen; Deng, Liang; Wang, Bing‐Wu; Gao, Song

doi:10.1021/jacs.6b11043

Cited by 369 publications

(239 citation statements)

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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%

“…[10,11] In the latter case, relaxation by quantum tunneling is usuallyv ery fast in zero field, so that application of astatic field is required to observeS MM behaviorb ya lternating-current (ac) susceptibility measurements. In particular, individual cobalt(II) ions were found to exhibit zero-field SMM behavior when embedded in tetrahedral, [14-17, 20, 22, 24] trigonal prismatic, [18,19,23] or linear [21] coordination environments or in as olid-state lattice. In particular, individual cobalt(II) ions were found to exhibit zero-field SMM behavior when embedded in tetrahedral, [14-17, 20, 22, 24] trigonal prismatic, [18,19,23] or linear [21] coordination environments or in as olid-state lattice.…”

Section: Introductionmentioning

confidence: 99%

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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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Section: Introductionmentioning

confidence: 99%

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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“…[3] Die Konstante D eines Spinzustandes ist eine Linearkombination der Nullfeldaufspaltungen der einzelnen Ionen. Derzeit sind Verbindungen mit Dysprosocenium [5][6][7] und niederkoordinierten Übergangsmetallionen [8,9] die geeignetsten Systeme,w obei vierfach koordinierte Cobalt(II)-Komplexe Beispiele der zuletzt genannten Verbindungsklasse darstellen. Derzeit sind Verbindungen mit Dysprosocenium [5][6][7] und niederkoordinierten Übergangsmetallionen [8,9] die geeignetsten Systeme,w obei vierfach koordinierte Cobalt(II)-Komplexe Beispiele der zuletzt genannten Verbindungsklasse darstellen.…”

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“…Die beste Übereinstimmung wurde mit den Werten J Co- [19] erhaltenen Orbitale wurden als Ausgangspunkt füre ine nachfolgende Rechnung verwendet, bei der der Brückenligand durch die Entnahme des zuvor zum HOMO hinzugefügten Elektrons wieder als offenschaliger Ligand behandelt wurde.B ei der Berechnung des Systems mit zwei offenen Schalen bedienten wir uns der SA-CASSCF-Methode,w obei sich der aktive Raum aus den fünf d-Orbitalen des Cobalts sowie den Grenzorbitalen des Brückenliganden (zwei p-u nd zwei p * -Orbitale,a lso CAS- (10,9)) zusammensetzte.Sowohl fürdas Quintett als auch für das Tr iplett wurden je zehn Zustände berechnet. Die Darstellung der Nullfeldaufspaltung erfordert die Berücksichtigung von Spin-Bahn-Wechselwirkungen, wohingegen Super-Austauschwechselwirkungen die Berücksichtigung von dynamischen Korrelationen erfordern.…”

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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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Encyclopedia of Inorganic and Bioinorganic Chemistry

Giansiracusa

Gransbury²,

Chilton

et al. 2011

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Single-Molecule Magnets (SMMs) are finite molecular species that display slow relaxation of their magnetisation, equivalent to a magnetic memory effect. Here we give an overview of how SMM behaviour can arise from the spin properties of a giant molecular spin or unpaired electrons on a single metal centre. We outline the criteria for obtaining SMM properties, and how these have developed through theoretical insight to lead to the rapid advancement of SMM performance. We discuss the progression of the field from the original Mn12 polymetallic cluster, to carefully engineered coordination complexes of Ln ions. Classes of compounds discussed include 3d, 3d-4f and 4f polymetallic clusters, 3d and 4f monometallic complexes, and homo-and hetero-metallic exchange-coupled SMMs, including those bridged by radical ligands and/or encapsulated in endohedral fullerenes. The state-ofthe-art in SMMs is discussed, leaving the reader with an up-to-date understanding of theory and synthetic design, with references to comprehensive reviews.For readers new or returning to the area, we highlight the standard experiments used to characterise SMMs -including magnetic hysteresis, zero-field cooled/field cooled magnetic susceptibility, alternating current susceptibility and magnetisation decay measurements. We highlight the common pitfalls often encountered in the literature in measurements, data analysis and structural correlation of properties. We aim to provide a clear background for relaxation mechanisms in SMMs and the quantification of performance using energy barriers, blocking temperatures and relaxation rate. The reader is directed towards a series of proof-ofconcept publications which have spearheaded the implementation of SMMs towards future applications in high density data storage, quantum information processing and spintronics.

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Two-Coordinate Co(II) Imido Complexes as Outstanding Single-Molecule Magnets

Cited by 369 publications

References 59 publications

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

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

Encyclopedia of Inorganic and Bioinorganic Chemistry

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