Magnetic exchange in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mi>α</mml:mi></mml:math>-iron from<i>ab initio</i>calculations in the paramagnetic phase

Igoshev, P. A.; Efremov, A. I.; Катанин, А. А.

doi:10.1103/physrevb.91.195123

Cited by 31 publications

(55 citation statements)

References 25 publications

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“…Moreover, one can see the crucial role of the E g − T 2g interactions on the ferromagnetism of iron: it provides the dominant FM component of the J 1 coupling. This observation is in line with a recent study by Igoshev et al 21 who analysed the paramagnetic susceptibility in bcc Fe and also emphasised an importance of the mixed E g −T 2g interactions for the formation of the local moment. The results shown in Fig.…”

Section: 28supporting

confidence: 91%

Microscopic Origin of Heisenberg and Non-Heisenberg Exchange Interactions in Ferromagnetic bcc Fe

et al. 2016

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By means of first principles calculations we investigate the nature of exchange coupling in ferromagnetic bcc Fe on a microscopic level. Analyzing the basic electronic structure reveals a drastic difference between the 3d orbitals of Eg and T2g symmetries. The latter ones define the shape of the Fermi surface, while the former ones form weakly-interacting impurity levels. We demonstrate that, as a result of this, in Fe the T2g orbitals participate in exchange interactions, which are only weakly dependent on the configuration of the spin moments and thus can be classified as Heisenberg-like. These couplings are shown to be driven by Fermi surface nesting. In contrast, for the Eg states the Heisenberg picture breaks down, since the corresponding contribution to the exchange interactions is shown to strongly depend on the reference state they are extracted from. Our analysis of the nearest-neighbour coupling indicates that the interactions among Eg states are mainly proportional to the corresponding hopping integral and thus can be attributed to be of double-exchange origin.Iron is one of the most abundant elements in the universe. Its elemental phase has several polymorphs and among those the most stable crystal structure at ambient conditions is a body-centered cubic (bcc) one. Ferromagnetism is known to play a decisive role in defining the stability of this structure.1,2 The bcc phase is ferromagnetic (FM) up to critical temperature (T c ) of 1045 K. Quite importantly, above the Curie point, the bcc structure is preserved in a certain temperature range before it undergoes a transition to the fcc phase. This fact implies that the local magnetic moments exist in the paramagnetic (PM) phase, where strong short-ranged magnetic order was proposed.3 The magnetism of Fe is of mixed itinerant and localised nature and it is a matter of debate, which model describes it the best. Both the T c and the magnetic excitation spectra at low temperatures can be well described by means of the Heisenberg Hamiltonian (HH), parameterised by ab initio calculations.4-10 However, in several works 11,12 it was argued that in order to describe a large palette of magnetic states, higher-order (biquadratic) exchange interactions have to be taken into account. The results of the self-consistent spin spiral calculations also indicate that the magnitude of the magnetic moment in bcc Fe can differ by almost 30% in various states, 13,14 which in principle disagrees with the assumptions of the Heisenberg picture. Indeed, it was previously pointed out that the parameterisation of HH for bcc Fe depends on the magnetic configuration they are extracted from. 15-17The strong correlation effects are known to be important for bcc Fe at finite temperatures, as was shown in Ref. 18 by means of density functional theory plus dynamical mean field theory (DFT+DMFT) calculations.Earlier, it was suggested from a qualitative analysis of the electronic structure that the E g electrons in iron are much more correlated than the T 2 g ones.19 This statement was qua...

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Section: 28supporting

confidence: 91%

Microscopic Origin of Heisenberg and Non-Heisenberg Exchange Interactions in Ferromagnetic bcc Fe

et al. 2016

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“…To treat the effect of local correlations we apply in the present paper the combination of dynamical mean-field theory (DMFT) 10 with density functional theory (DFT) methods, usually called LDA+DMFT 11 . Previous studies by LDA+DMFT allowed one to obtain the correct values of magnetic moments in α and γ phases [12][13][14][15][16] , the linear behavior of the temperature dependence of the inverse local [13][14][15][16] (α,γ phases) and uniform magnetic 12,17,18 (α phase) susceptibilities, and revealed the non-monotonic temperature dependence of inverse the uniform magnetic susceptibility in the γ phase in a broad temperature range 14 .…”

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“…15; χ loc (iω n ) is the dynamic local susceptibility and χ irr ≈ 2µ 2 B /eV is the static local two-particle irreducible susceptibility in the α phase. Decoupling the four-spin interaction in the soft constraint part in Eq.…”

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confidence: 99%

“…is the exchange interaction, χ irr q is the static two-particle irreducible susceptibility, which can be calculated as a bubble, constructed from itinerant Green functions 15 . The determination of the function Λ(T, iω n ) is a rather complicated problem, since it requires knowledge of the S 2 2 interaction potential in Eq.…”

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confidence: 99%

“…To calculate the nonlocal corrections to the Curie temperature and the energy of the α phase, we treat the effect of local moments on the energy within the spin-fermion model of Ref. 15, supplemented by a soft spin constraint,…”

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Nonlocal correlations in the vicinity of the α−γ phase transition in iron within a DMFT plus spin-fermion model approach

2016

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We consider nonlocal correlations in iron in the vicinity of the α-γ phase transition within the spinrotationally-invariant dynamical mean-field theory (DMFT) approach, combined with the recently proposed spin-fermion model of iron. The obtained nonlocal corrections to DMFT yield a decrease of the Curie temperature of the α phase, leading to an agreement with its experimental value. We show that the corresponding nonlocal corrections to the energy of the α phase are crucially important to obtain the proximity of energies of α and γ phases in the vicinity of the iron α-γ transformation.

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Magnetic exchange inα-iron fromab initiocalculations in the paramagnetic phase

Cited by 31 publications

References 25 publications

Microscopic Origin of Heisenberg and Non-Heisenberg Exchange Interactions in Ferromagnetic bcc Fe

Microscopic Origin of Heisenberg and Non-Heisenberg Exchange Interactions in Ferromagnetic bcc Fe

Nonlocal correlations in the vicinity of the α−γ phase transition in iron within a DMFT plus spin-fermion model approach

Extracting Kondo temperature of strongly-correlated systems from the inverse local magnetic susceptibility

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