Modelling spin Hamiltonian parameters of molecular nanomagnets

Gupta, Tarkeshwar; Rajaraman, Gopalan

doi:10.1039/c6cc01251e

Cited by 76 publications

(67 citation statements)

References 297 publications

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“…The g values of these three complexes are totally isotropic in nature, 2.00, as the g value depends only on the ground electronic state. The sign of D SOC here cannot be rationalized using the M L value of the d-orbitals and their excitation, as has been routinely done in other cases, 35 as here the contributions arise solely due to spin-flip transitions. 36 Despite the significant structural variations observed, the magnitude of the computed D values is nearly the same in all three complexes.…”

Section: Theoretical Calculationsmentioning

confidence: 94%

Investigation of the magnetic anisotropy in a series of trigonal bipyramidal Mn(ii) complexes

et al. 2019

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Understanding how the magnetic anisotropy in simple coordination complexes can be manipulated is instrumental to the development of single-molecule magnets (SMMs). Clear strategies can then be designed to control both the axial and transverse contributions to the magnetic anisotropy in such compounds, and allow them to reach their full potential. Here we show a strategy for boosting the magnetic anisotropy in a series of trigonal bipyramidal Mn(II) complexes -[MnCl 3 (HDABCO)(DABCO)] (1), [MnCl 3 (MDABCO) 2 ]·[ClO 4 ] (2), and [MnCl 3 (H 2 O)(MDABCO)] (3). These have been successfully synthesised using the monodentate [DABCO] and [MDABCO] + ligands. Through static (DC) magnetic measurementsand detailed theoretical investigation using ab initio methods, the magnetic anisotropy of each system has been studied. The calculations reveal that the rhombic zero-field splitting (ZFS) term (E) can be tuned as the symmetry around the Mn(II) ion is changed. Furthermore, an in silico investigation reveals a strategy to increase the axial ZFS parameter (D) of trigonal bipyramidal Mn(II) by an order of magnitude. † Electronic supplementary information (ESI) available: Crystallographic data, selected bond lengths and angles, crystal packing diagrams, information on SHAPE studies conducted, powder X-ray diffraction for complexes 1-3, and further magnetic data. CCDC 1881218-1881220. For ESI and crystallographic data in CIF or other electronic format see

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Section: Theoretical Calculationsmentioning

confidence: 94%

Investigation of the magnetic anisotropy in a series of trigonal bipyramidal Mn(ii) complexes

et al. 2019

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“…Moreover, one can distinguish the eigenvalues of tetramer Hamiltonian corresponding to m = 0 and m = 0, with S zz (q, ω n n ) = 0 and S xx (q, ω n n ) = 0, S yy (q, ω n n ) = 0, respectively. This affects directly the integrated intensities, such that choosing r 12 = (0, 0, r z ) and r 34 = (r x , 0, 0) from (2.1) yields I 10 ∝ γ 10…”

Section: B Scattering Intensitiesmentioning

confidence: 99%

“…The physical properties, such as energy spectra, susceptibility, etc., of magnetic clusters at the nanoscale depend on their size, shape and the presence of different bondings among the constituent chemical elements and thus the distribution of ligands between the magnetic ions (for more details see [1][2][3][4] and references therein). Some prominent examples are Mn based magnetic compounds [5][6][7][8][9][10][11] and spin clusters with Ni magnetic ions [12][13][14][15] .…”

Section: Introductionmentioning

confidence: 99%

“…Here, the present method will be validated by reproducing the experimentally obtained INS spectrum of a molecular magnet that has generated a great deal of interest among researchers both on the theoretical, as well as the experimental sides. This is the magnetic molecule [Mo 12 O 30 (µ 2 -OH) 10 30 . We would like to point out that previous studies 31,32 did not succeed to obtain the main peaks and the broadening in the INS spectrum, see FIG.…”

Section: Introductionmentioning

confidence: 99%

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Magnetic excitations in molecular magnets with complex bridges: the tetrahedral molecule Ni4Mo12

Georgiev

Chamati

2019

Eur. Phys. J. B

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We investigate the spectroscopic magnetic excitations in molecular magnets with complex intermediate structure among the magnetic ions. Our approach consists in introducing a modified spin Hamiltonian that allows for discrete coupling parameters accounting for all energetically favorable spatial distributions of the valence electrons along the exchange bridges connecting the constituent magnetic ions. We discuss the physical relevance of the constructed Hamiltonian and derive its eigenvalues. The model is applied to explore the magnetic excitations of the tetrameric molecular magnet Ni 4 Mo 12 . Our results are in a very good agreement with the available experimental data. We show that the experimental magnetic excitations in the named tetramer can be traced back to the specific geometry and complex chemical structure of the exchange bridges leading to the splitting and broadness of the peaks centered about 0.5 meV and 1.7 meV.

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“…According to the prediction of previous studies [7], fractures are clearly visible. Many fractures can be seen in the samples due to that stress during the drying time or the annealing process.…”

Section: Resultsmentioning

confidence: 95%

Fabrication of TiO2 Nanoscale Thin Film and Its Structural Properties

Ebrahim-Zadeh¹,

Bilankohi²

2016

HJBC

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Ö Z E TO lağanüstü kararlılıktaki titanyum dioksit fotokatalitik özellikleri nedeniyle kimya endüstrisinde potansiyel uygulamalara sahiptir. Titanyum dioksit nanopartiküller sol-jel yöntemi ile sentezlenmiş ve daldırmalı kaplama yöntemi ile cam yüzey üzerine ince film hazırlamak için kullanılmıştır. Örneklerin yapısal ve fiziksel özelliklerini karaterize etmek için XRD, UV-VIS ve optik mikroskop kullanılmıştır. Sonuçlar yakma sıcaklığı ve kalınlık arttıkça, partikül boyutunun arttığını ve enerji aralığının azaldığını göstermiştir. Enerji aralığı kontrollü yarı iletkenler, yakma sıcaklığını ve kalınlığı kontrol ederek üretilebilir. Anahtar KelimelerNano ölçek ince film, TiO 2 , yarı iletken, dip kaplama. A B S T R A C TT he photocatalytic properties of titanium dioxide with extraordinary stability have potential application in chemical industry. Titanium dioxide nanoparticles were synthesized by sol-gel method and used dip-coating method for the preparation of thin films on glass substrate. To study the structural and physical characteristics of the samples, the XRD, UV-VIS and an optical microscope were used. The results show that with increasing the annealing temperature and thickness, larger particle size obtained and energy gap is reduced. Thus, by controlling the annealing temperature and thickness can be achieved to the gap-controlled semiconductors.

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Modelling spin Hamiltonian parameters of molecular nanomagnets

Cited by 76 publications

References 297 publications

Investigation of the magnetic anisotropy in a series of trigonal bipyramidal Mn(ii) complexes

Investigation of the magnetic anisotropy in a series of trigonal bipyramidal Mn(ii) complexes

Magnetic excitations in molecular magnets with complex bridges: the tetrahedral molecule Ni4Mo12

Fabrication of TiO2 Nanoscale Thin Film and Its Structural Properties

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