Amending the Anisotropy Barrier and Luminescence Behavior of Heterometallic Trinuclear Linear [MIILnIIIMII] (LnIII=Gd, Tb, Dy; MII=Mg/Zn) Complexes by Change from Divalent Paramagnetic to Diamagnetic Metal Ions

Das, Sourav; Bejoymohandas, K. S.; Dey, Atanu; Biswas, Sourav; Reddy, M. L. P.; Roser, Morales; Ruiz, Eliseo; Titos-Padilla, Silvia; Colacio, Enrique; Chandrasekhar, Vadapalli

doi:10.1002/chem.201406666

Cited by 64 publications

(50 citation statements)

References 108 publications

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“…Recently, we have been experimenting with various types of ligands for the purpose of knowing their discriminatory capability in terms of directing homonuclear lanthanide assemblies versus heteronuclear 3d/4f complexes 11. Thus, the ligands, 2‐(hydroxymethyl)‐6‐carbaldehyde‐4‐methylphenol ( C2 ) and the Schiff base derivative (2‐(2‐hydroxy‐3‐(hydroxymethyl)‐5‐methylbenzylideneamino)‐2‐methylpropane1,3‐diol) afforded pentanuclear M 4 Ln11a, b and M 2 Ln11c, d, e derivatives respectively (Scheme ).…”

Section: Resultsmentioning

confidence: 99%

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Decanuclear Ln₁₀ Wheels and Vertex‐Shared Spirocyclic Ln₅ Cores: Synthesis, Structure, SMM Behavior, and MCE Properties

Das

Dey

Kundu

et al. 2015

Chemistry A European J

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The reaction of a Schiff base ligand (LH3) with lanthanide salts, pivalic acid and triethylamine in 1:1:1:3 and 4:5:8:20 stoichiometric ratios results in the formation of decanuclear Ln10 (Ln = Dy (1), Tb (2), and Gd (3)) and pentanuclear Ln5 complexes (Ln = Gd (4), Tb (5), and Dy (6)), respectively. The formation of Ln10 and Ln5 complexes are fully governed by the stoichiometry of the reagents used. Detailed magnetic studies on these complexes (1-6) have been carried out. Complex 1 shows a SMM behavior with an effective energy barrier for the reversal of the magnetization (Ueff) = 16.12(8) K and relaxation time (τo) = 3.3×10(-5) s under 4000 Oe direct current (dc) field. Complex 6 shows the frequency dependent maxima in the out-of-phase signal under zero dc field, without achieving maxima above 2 K. Complexes 3 and 4 show a large magnetocaloric effect with the following characteristic values: -ΔSm = 26.6 J kg(-1) K(-1) at T = 2.2 K for 3 and -ΔSm = 27.1 J kg(-1) K(-1) at T = 2.4 K for 4, both for an applied field change of 7 T.

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Section: Resultsmentioning

confidence: 99%

“… a) Pentanuclear M 4 Ln11a, b and b) trinuclear M 2 Ln11c, d, e derived from C2 and its Schiff base derivative, respectively. …”

Section: Resultsmentioning

confidence: 99%

Decanuclear Ln₁₀ Wheels and Vertex‐Shared Spirocyclic Ln₅ Cores: Synthesis, Structure, SMM Behavior, and MCE Properties

Das

Dey

Kundu

et al. 2015

Chemistry A European J

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“…178 We have also performed extensive calculations on {Dy-OH} models with varying coordination number around Dy III and number of coordinated -OH ligands. 181 Experiments clearly revealed Zn II -Dy III -Zn II unit as an origin of magnetic relaxation rather than intermolecular interactions/long range ordering.…”

Section: G Tensor Magnetic Anisotropy Of Lanthanide Complexesmentioning

confidence: 97%

Modelling spin Hamiltonian parameters of molecular nanomagnets

Gupta

Rajaraman

2016

Chem. Commun.

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Molecular nanomagnets encompass a wide range of coordination complexes possessing several potential applications. A formidable challenge in realizing these potential applications lies in controlling the magnetic properties of these clusters. Microscopic spin Hamiltonian (SH) parameters describe the magnetic properties of these clusters, and viable ways to control these SH parameters are highly desirable. Computational tools play a proactive role in this area, where SH parameters such as isotropic exchange interaction (J), anisotropic exchange interaction (Jx, Jy, Jz), double exchange interaction (B), zero-field splitting parameters (D, E) and g-tensors can be computed reliably using X-ray structures. In this feature article, we have attempted to provide a holistic view of the modelling of these SH parameters of molecular magnets. The determination of J includes various class of molecules, from di- and polynuclear Mn complexes to the {3d-Gd}, {Gd-Gd} and {Gd-2p} class of complexes. The estimation of anisotropic exchange coupling includes the exchange between an isotropic metal ion and an orbitally degenerate 3d/4d/5d metal ion. The double-exchange section contains some illustrative examples of mixed valance systems, and the section on the estimation of zfs parameters covers some mononuclear transition metal complexes possessing very large axial zfs parameters. The section on the computation of g-anisotropy exclusively covers studies on mononuclear Dy(III) and Er(III) single-ion magnets. The examples depicted in this article clearly illustrate that computational tools not only aid in interpreting and rationalizing the observed magnetic properties but possess the potential to predict new generation MNMs.

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“…Counterintuitively, a diamagnetic metal ion linked to the lanthanide ion by a single atom bridge (such as oxide ion) seems to enhance the binding capacity of the oxide and help in increasing the energy gap between the ground the excited states of the lanthanide ions leading to more favorable magnetic properties –. Accordingly, isostructural, linear [Mg II 2 Ln III ] 3+ [Ln III =Gd III ( 167 ), Tb III ( 168 ) and Dy III ( 169 )] and [Zn II 2 Ln III ] 3+ (Ln III =Gd III ( 170 ), Tb III ( 171 ) and Dy III ( 172 )] complexes, analogous to the previously discussed systems, [Co II 2 Ln III ] 3+ and [Ni II 2 Ln III ] 3+ (vide supra) were synthesized by employing [2‐(2‐hydroxy‐3‐(hydroxymethyl)‐5‐methylbenzylideneamino)‐2‐methylpropane‐1,3‐diol] (L 16 H 4 ) . The Mg II or Zn II ions are present in the terminal positions and have a coordination environment comprising of four O atoms and two N atoms in a distorted octahedral geometry.…”

Section: Znii/mgii‐lniii Complexesmentioning

confidence: 99%

Heterometallic 3d–4f Complexes as Single‐Molecule Magnets

Dey

Acharya

Chandrasekhar

2019

Chemistry An Asian Journal

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Heterometallic 3d-4fc omplexes are being investigated, for some time, as being useful in molecular magnetism, particularly as single-molecule magnets (SMMs). This interest is primarily because of the possibility of an increased ligand-mediated super-exchange phenomenon between the 3d and 4f metal ions. Such an interaction, apart from bestowing af avorable ground-state spin to the complex, also assists in reducing quantum tunneling of magnetization that is widely prevalenti nS MMs making them to lose magnetization. However,a ssembling both 3d as well as 4f ions using same ligand system is challenging and involves the design of multi-site coordination ligandsw ith specific coordination compartments for the 3d and the 4f metal ions while at the same time allowing these disparate metal ions to be linked to each other through ab ridging ligatinga tom. This review presents as ummary of the 3d-4f complexes primarily derived from the author's work while alluding to importante xamplesf rom the literature. We also provide an outlookf or the future design of such complexes.[a] Dr.A .Dey, Prof. V. Chandrasekhar 4434Minireview dro-imidazol-2-ylidenea nd DmpN 3 = 2,6-dimesitylphenyl azide] which exhibit slow magnetic relaxation with U eff values of 450 and 413 cm À1 respectively. [13][14][15] Similarly,t here have been reports on mononuclear lanthanide complexes [12a, 16] ever since the seminalp aper on the first lanthanide based SMM in 2003, (Bu 4 N)[Ln III (Pc) 2 ] [17] [Ln III = Tb III (7)a nd Dy III (8); Pc = phthalocyaninato].R ecently,t he complexes [(Cp ttt ) 2 Dy III ][B(C 6 F 5 ) 4 ] [18] (9) (Cp ttt [19] (10)h ave been reported with blockingt emperatures of 60 and 80 Kr espectively.C omplex 10 holds the record for the highest reported energy barrier U eff = 1541 cm À1 for the reversal of magnetization.One of the problemsa ssociated with SMMs is that the magnetization can be lost by av ariety of ways including quantum tunneling mechanism (QTM) which shortcuts the energy barriers of relaxation. [6b] This is an important impediment and progress in this field is dependent on minimizing or eliminating QTM. There are many strategies to do this including assembling mononuclear complexes possessing point-group symmetries such as C 1v , D 1h , S 8 (I 4 ), D 4d , D 5d and D 5h[12a] or by increasing the ferromagnetic coupling between the adjacent lanthanide centers,a ne xample of this being the dinuclearc omplex [K(18crown-6)]{[((Me 3 Si) 2 n) 2 (THF)Dy III ] 2 (m-h 2 :h 2 -N 2 )} (11)w here the radicall igand, N 2 3À , [20] facilitates af erromagnetic exchange between the two lanthanide centers. [21] Another strategy is to involve heterometallic transition metal/lanthanide complexes where as uper-exchange ferromagnetic interaction between the lanthanide and transition metal ion can mitigate QTM. [22] Accordingly,t he first 3d-4fb ased SMM, a[ Cu II 2 Tb III 2 ]( 12) complex, was reported by Osa and co-workers in 2004. [23] Murray and co-workers have successfully utilized this strategy for av ariety of complexes with {Cr II...

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Amending the Anisotropy Barrier and Luminescence Behavior of Heterometallic Trinuclear Linear [M^IILn^IIIM^II] (Ln^III=Gd, Tb, Dy; M^II=Mg/Zn) Complexes by Change from Divalent Paramagnetic to Diamagnetic Metal Ions

Cited by 64 publications

References 108 publications

Decanuclear Ln₁₀ Wheels and Vertex‐Shared Spirocyclic Ln₅ Cores: Synthesis, Structure, SMM Behavior, and MCE Properties

Decanuclear Ln₁₀ Wheels and Vertex‐Shared Spirocyclic Ln₅ Cores: Synthesis, Structure, SMM Behavior, and MCE Properties

Modelling spin Hamiltonian parameters of molecular nanomagnets

Heterometallic 3d–4f Complexes as Single‐Molecule Magnets

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Amending the Anisotropy Barrier and Luminescence Behavior of Heterometallic Trinuclear Linear [MIILnIIIMII] (LnIII=Gd, Tb, Dy; MII=Mg/Zn) Complexes by Change from Divalent Paramagnetic to Diamagnetic Metal Ions

Cited by 64 publications

References 108 publications

Decanuclear Ln10 Wheels and Vertex‐Shared Spirocyclic Ln5 Cores: Synthesis, Structure, SMM Behavior, and MCE Properties

Decanuclear Ln10 Wheels and Vertex‐Shared Spirocyclic Ln5 Cores: Synthesis, Structure, SMM Behavior, and MCE Properties

Modelling spin Hamiltonian parameters of molecular nanomagnets

Heterometallic 3d–4f Complexes as Single‐Molecule Magnets

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Product

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Amending the Anisotropy Barrier and Luminescence Behavior of Heterometallic Trinuclear Linear [M^IILn^IIIM^II] (Ln^III=Gd, Tb, Dy; M^II=Mg/Zn) Complexes by Change from Divalent Paramagnetic to Diamagnetic Metal Ions

Decanuclear Ln₁₀ Wheels and Vertex‐Shared Spirocyclic Ln₅ Cores: Synthesis, Structure, SMM Behavior, and MCE Properties

Decanuclear Ln₁₀ Wheels and Vertex‐Shared Spirocyclic Ln₅ Cores: Synthesis, Structure, SMM Behavior, and MCE Properties