Stabilization of<i>d</i>-band ferromagnetism by hybridization with uncorrelated bands

Schwieger, S.; Nolting, Wolfgang

doi:10.1103/physrevb.64.144415

Cited by 10 publications

(20 citation statements)

References 28 publications

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“…The coupling between the localized d-states of Mn and p-or d-states of As, already deemed responsible by older double-exchange theory [10], indeed drives the transition from the paramagnetic to the ferromagnetic state. This is confirmed by density functional theory [11] and a recent two-band Hubbard-model study claiming that a small change in p-d hybridization can give a 'final kick' to a system that is close to a ferromagnetic transition [12]. …”

supporting

confidence: 74%

Evolution of stress and magnetism during the first-order phase transition of MnAs/GaAs(001)

Ney

Das

Pampuch

et al. 2004

Journal of Magnetism and Magnetic Materials

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supporting

confidence: 74%

Evolution of stress and magnetism during the first-order phase transition of MnAs/GaAs(001)

Ney

Das

Pampuch

et al. 2004

Journal of Magnetism and Magnetic Materials

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“…We want now to exhibit the combined effect of V , α and s on this process at T = 0K, for each n tot . Schwieger and Nolting [3] address to the same problem using methods similar to ours, the Spectral density approach (SDA) and the Modified Alloy analogy (MAA) both giving rise to a band shift. There are nevertheless some differences: their methods do not arrive at a self-consistency equation so they make an expansion in V and 1 w and find the self-energy analytically in some approximation.…”

Section: The Methods and Numerical Resultsmentioning

confidence: 92%

“…Magnetism in itinerant ferromagnets still attracts great interest [1][2][3][4][5][6][7][8][9][10][11]. It is then relevant to propose, use and test models on this subject and analyze their effectiveness, what we do in this paper for a specific model.…”

Section: Introductionmentioning

confidence: 98%

Ferromagnetism in two band metals: The very strong coupling limit

Chaves¹,

Calegari²,

Magalhães³

et al. 2015

Physica B: Condensed Matter

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“…Bernhard [2] addresses the correlated one-band problem, while Schwieger and Nolting [3] treats also a hybridized twoband model using the spectral density approach (SDA) and a modified alloy analogy. Their approach is equivalent to the socalled Hubbard I [5] while ours is equivalent rather to Hubbard III [6].…”

Section: Formulation Of the Problemmentioning

confidence: 99%

Ferromagnetism in two band metals: Combined effect of Coulomb correlation, hybridization and band widths

Chaves¹,

Troper²

2010

Journal of Magnetism and Magnetic Materials

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a b s t r a c tWe study the possibility of ferromagnetism in metals. The metal is described by two hybridized bands one of which includes Hubbard correlation whereas the other is uncorrelated. We parametrize the ratio of the band widths and their centers as well. The original Hamiltonian is transformed into an effective and simpler one. Only one site retains the full correlation (U) while in the others acts as an internal field, the self-energy, in the framework of an alloy analogy approximation. This field, in turn, is selfconsistently determined by imposing the translational invariance of the problem. For several total electronic occupation numbers (n total ) we compare the spin dependent free energies with the corresponding paramagnetic ones. We present several results pointing out the mechanism by which the self-consistency introduces a sort of constraints, for given values of band width and band shift.& 2009 Elsevier B.V. All rights reserved. Formulation of the problemThe origin of magnetism in itinerant ferromagnets has been object of concern in last years [1][2][3][4]. We use a two band model to describe the effect of Coulomb correlation in these metals. It consists of a Hubbard like narrow band (band a) with intrasite Coulomb interaction U, hybridized with another band, which is broad and uncorrelated (band b), through the hybridization coupling V ab . We allow a shift between the centers of the two bands and a variation of the b-band width as well, in order to describe a more general and realistic band structure. Both have strong influence on the kind of magnetic state of the metal.As in Roth's approach [8], the correlation is present in only one site (say, the origin), while in the others acts an effective spin and energy dependent but site independent field, the self-energy S s . This field is self-consistently determined by imposing the vanishing of the scattering T matrix associated to the origin, thus restoring the translational invariance of the host.Bernhard [2] addresses the correlated one-band problem, while Schwieger and Nolting [3] treats also a hybridized twoband model using the spectral density approach (SDA) and a modified alloy analogy. Their approach is equivalent to the socalled Hubbard I [5] while ours is equivalent rather to Hubbard III [6]. Our effective Hamiltonian is [7]

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Stabilization ofd-band ferromagnetism by hybridization with uncorrelated bands

Cited by 10 publications

References 28 publications

Evolution of stress and magnetism during the first-order phase transition of MnAs/GaAs(001)

Evolution of stress and magnetism during the first-order phase transition of MnAs/GaAs(001)

Ferromagnetism in two band metals: The very strong coupling limit

Ferromagnetism in two band metals: Combined effect of Coulomb correlation, hybridization and band widths

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