From antiferromagnetic to ferromagnetic exchange in a family of oxime-based MnIII dimers: a magneto-structural study

Barros, Wdeson P.; Inglis, Ross; Nichol, Gary S.; Rajeshkumar, Thayalan; Rajaraman, Gopalan; Piligkos, Stergios; Stumpf, Humberto O.; Brechin, Euan K.

doi:10.1039/c3dt52009a

Cited by 34 publications

(24 citation statements)

References 85 publications

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“…Although the magnitude of the D values are comparatively smaller for the Mn III ions (in the range of ±4 cm -1 ) 192 , the sign is predictable (<0 cm -1 for elongated octahedral complexes) and thus it is a popular choice for the synthetic chemists. 30 The complexes studied are categorized as type-I (see Figure 3a) and possess strong antiferromagnetic interactions, as expected. In relevance to this, we have probed three different types of bis-µ-alkoxo bridged Mn III dimeric complexes are rationalized based on the MO analysis where in type III dimers, due to the perpendicular orientation of the J-T distortions, significant orbital overlaps are avoided and cross interaction between empty and the single-occupied orbital enhances leading to a strong ferromagnetic coupling (see Figure 2b).…”

Section: Regulating Isotropic J For Mn Based Dinuclear Complexessupporting

confidence: 68%

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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Section: Regulating Isotropic J For Mn Based Dinuclear Complexessupporting

confidence: 68%

Modelling spin Hamiltonian parameters of molecular nanomagnets

Gupta

Rajaraman

2016

Chem. Commun.

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“…The family of dimeric species [Mn 2 O(R-sao)(tpa) 2 ](ClO 4 )] 2 (R-saoH 2 = R-salicylaldoxime, with R = H, Et and Ph, and tpa = tris (2-pyridylmethyl)amine) have been recently reported, where the manganese(III) ions are linked by a Mn–N–O–Mn oxime and an Mn–O–Mn oxido bridge leading to AFM coupling with J = −4.94, −3.87, −5.17 cm −1 for R = H, Et, Ph, respectively [ 45 ]. The related complexes (Mn 2 (R-sao) 2 (dpa) 2 )(ClO 4 ) 2 (R = H, Me, Et and Ph, and dpa = di(2-picolyl)amine), having two Mn–N–O–Mn oxime bridges, display AFM coupling with J = −5.73, −3.63, −5.63, –2.05 cm −1 for R = H, Me.…”

Section: Resultsmentioning

confidence: 99%

Selective Formation, Reactivity, Redox and Magnetic Properties of MnIII and FeIII Dinuclear Complexes with Shortened Salen-Type Schiff Base Ligands

Rigamonti

Zardi

Carlino

et al. 2020

IJMS

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The reactivity of the shortened salen-type ligands H3salmp, H2salmen and H2sal(p-X)ben with variable para-substituent on the central aromatic ring (X = tBu, Me, H, F, Cl, CF3, NO2) towards the trivalent metal ions manganese(III) and iron(III) is presented. The selective formation of the dinuclear complexes [M2(-salmp)2], M = Mn (1a), Fe (2a), [M2(-salmen)2(-OR)2)], R = Et, Me, H and M = Mn (3a–c) or Fe (4a–c), and (M2(-sal[p-X]ben)2(-OMe)2), X = tBu, Me, H, F, Cl, CF3, NO2 and M = Mn (5a–g) or Fe (6a–g), could be identified by reaction of the Schiff bases with metal salts and the base NEt3, and their characterization through elemental analysis, infrared spectroscopy, mass spectrometry and single-crystal X-ray diffraction of 2a2AcOEt, 2a2CH3CN and 3c2DMF was performed. In the case of iron(III) and H3salmp, when using NaOH as a base instead of NEt3, the dinuclear complexes [Fe2(-salmp)(-OR)(salim)2], R = Me, H (2b–c) could be isolated and spectroscopically characterized, including the crystal structure of 2b1.5H2O, which showed that rupture of one salmp3– to two coordinated salim– ligands and release of one salH molecule occurred. The same hydrolytic tendency could be identified with sal(p-X)ben ligands in the case of iron(III) also by using NEt3 or upon standing in solution, while manganese(III) did not promote such a C–N bond breakage. Cyclic voltammetry studies were performed for 3b, 4b, 5a and 6a, revealing that the iron(III) complexes can be irreversibly reduced to the mixed-valence FeIIFeIII and FeII2 dinuclear species, while the manganese(III) derivatives can be reversibly oxidized to either the mixed-valence MnIIIMnIV or to the MnIV2 dinuclear species. The super-exchange interaction between the metal centers, mediated by the bridging ligands, resulted in being antiferromagnetic (AFM) for the selected dinuclear compounds 3b, 4b, 5a, 5e, 5f, 6a and 6e. The coupling constants J (–2J Ŝ1·Ŝ2 formalism) had values around –13 cm–1 for manganese(III) compounds, among the largest AFM coupling constants reported so far for dinuclear MnIII2 derivatives, while values between –3 and –10 cm–1 were obtained for iron(III) compounds.

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“…We have previously established a computational approach for reliably computing exchange coupling constants in dinuclear complexes using broken-symmetry DFT and this methodology has been employed here. [54][55][56] Results and discussion…”

Section: Computational Detailsmentioning

confidence: 99%

Magneto-structural correlations in a family of di-alkoxo bridged chromium dimers

et al. 2017

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A series of di-alkoxo bridged Cr(iii) dimers have been synthesised using pyridine alcohol ligands. The structures fall into four general categories and are of formula: [Cr(OMe)(pic)]·½MeOH·½EtO (1), [Cr(hmp)(pic)X] (where X = Cl (2), Br (3)), [Cr(L)Cl(A)]·2S (where L = hmp, A = HO and S = EtO (4); L = hmp, A = pyridine and S = pyridine (5); L = hmp, A = 4-picoline and no S (6); L = hep, A = HO and S = MeCN (7)), and [Cr(hmp)(hmpH)Cl]·MeCN (8). Direct current (DC) magnetic susceptibility measurements show relatively weak antiferromagnetic exchange interactions between the Cr(iii) centres with J values <|15| cm in all of the complexes measured. DFT calculations performed on complexes 1-8 reproduce both the sign and strength of the exchange interactions found experimentally, and confirm that the magnitude and sign of the J value is strongly dependent upon the orientation of the dihedral angle formed between the bridging CrO plane and the O-R vector of the bridging group (θ), and the Cr-O-Cr-O dihedral angle (ψ).

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From antiferromagnetic to ferromagnetic exchange in a family of oxime-based MnIII dimers: a magneto-structural study

Cited by 34 publications

References 85 publications

Modelling spin Hamiltonian parameters of molecular nanomagnets

Modelling spin Hamiltonian parameters of molecular nanomagnets

Selective Formation, Reactivity, Redox and Magnetic Properties of MnIII and FeIII Dinuclear Complexes with Shortened Salen-Type Schiff Base Ligands

Magneto-structural correlations in a family of di-alkoxo bridged chromium dimers

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