Electronic structure and magnetism of<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi mathvariant="normal">Fe</mml:mi></mml:mrow><mml:mrow><mml:mn>3</mml:mn><mml:mi>−</mml:mi><mml:mi>x</mml:mi></mml:mrow></mml:msub></mml:mrow><mml:mrow><mml:msub><mml:mrow><mml:mi mathvariant="normal">V</mml:mi></mml:mrow><mml:mrow><mml:mi>x</mml:mi></mml:mrow></mml:msub></mml:mrow><mml:mi>X</mml:mi></mml:math><mml:math xmlns:mml="http://www.w3.org/1998/Math/Mat

Bansil, Arun; Kaprzyk, S.; Mijnarends, P.E.; Toboła, J.

doi:10.1103/physrevb.60.13396

Cited by 375 publications

(267 citation statements)

References 79 publications

(124 reference statements)

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“…1 and 2 are based on the QP-GW model 16,29 , an extension of our earlier Hartree-Fock (HF) model of AFM gap collapse 5,6,31,32 to the intermediate coupling regime by introducing a GWlike self-energy correction. [33][34][35][36] The self-energy in QP-GW model is dominated by a broad peak in Σ ′′ which produces the 'waterfall' effect 17,18 in the electronic dispersion by redistributing spectral weight into the coherent in-gap states and an incoherent residue of the undressed UHB and LHB. With underdoping, the in-gap states develop a pseudogap which we model as a (π, π)-ordered spin density wave.…”

Section: Intermediate Coupling Model Of Aswtmentioning

confidence: 99%

Failure oft−Jmodels in describing doping evolution of spectral weight in x-ray scattering, optical, and photoemission spectra of cuprates

2010

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We have analyzed experimental evidence for an anomalous transfer of spectral weight from high to low energy scales in both electron and hole doped cuprates as a function of doping. X-ray scattering, optical and photoemission spectra are all found to show that the high energy spectral weight decreases with increasing doping at a rate much faster than predictions of the large U −limit calculations. The observed doping evolution is however well-described by an intermediate coupling scenario where the effective Hubbard U is comparable to the bandwidth. The experimental spectra across various spectroscopies are inconsistent with fixed-U exact diagonalization or quantum Monte Carlo calculations, and indicate a significant doping dependence of the effective U in the cuprates.

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Section: Intermediate Coupling Model Of Aswtmentioning

confidence: 99%

Failure oft−Jmodels in describing doping evolution of spectral weight in x-ray scattering, optical, and photoemission spectra of cuprates

2010

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“…[27] The crystal potential was constructed in the framework of the local density approximation (LDA), using von Barth and Hedin formula [28] for the exchangecorrelation part. For all atoms angular momentum cut- …”

Section: Electron-phonon Interaction and Superconductivitymentioning

confidence: 99%

Effect of the tetragonal distortion on the electronic structure, phonons and superconductivity in the Mo3Sb7 superconductor

Wiendlocha

Sternik

2014

Intermetallics

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Effect of tetragonal distortion on the electronic structure, dynamical properties and superconductivity in Mo3Sb7 is analyzed using first principles electronic structure and phonon calculations. Rigid muffin tin approximation (RMTA) and McMillan formulas are used to calculate the electron-phonon coupling constant λ and superconducting critical temperature. Our results show, that tetragonal distortion has small, but beneficial effect on superconductivity, slightly increasing λ, and the conclusion that the electron-phonon mechanism is responsible for the superconductivity in Mo3Sb7 is supported. The spin-polarized calculations for the ordered (ferromagnetic or antiferromagnetic), as well as disordered (disordered local moment) magnetic states yielded non-magnetic ground state. We point out that due to its experimentally observed magnetic properties the tetragonal Mo3Sb7 might be treated as noncentrosymmetric superconductor, which could have influence for the pairing symmetry. In this context the relativistic band structure is calculated and spin-orbit interaction effects are discussed.

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“…Although the superconducting properties of V 3 Al in the A15 structure have been known for several decades, [10][11][12][13] when synthesized in the pseudo-Heusler D0 3 structure V 3 Al is expected to be an AF gapless semiconductor. [2,6,7] The D0 3 structure has the same space group as the L2 1 structure, but the binary D0 3 structure has a X 3 Z basis, while the ternary L2 1 structure has a X 2 YZ basis.…”

Section: Introductionmentioning

confidence: 99%

“…Figure 1(c) illustrates the D0 3 structure of V 3 Al where the Al atom occupies the 4a Wyckoff position at (0,0,0), the V atom labeled V1 occupies the 4b position at (1/2, 1/2, 1/2), and the remaining two V atoms labeled V2 occupy the 8c position at (1/4, 1/4, 1/4). [11] The atoms along the cubic body diagonal have an Al-V2-V1-V2-Al configuration. The local environment of V1 includes eight V2 nearest-neighbors and six Al second-nearest-neighbors, whereas the V2 atoms have four Al and four V1 nearest-neighbors and six V2 second-nearest-neighbors.…”

Section: Introductionmentioning

confidence: 99%

Antiferromagnetic phase of the gapless semiconductorV3Al

et al. 2015

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Discovering new antiferromagnetic compounds is at the forefront of developing future spintronic devices without fringing magnetic fields. The antiferromagnetic gapless semiconducting D0 3 phase of V 3 Al was successfully synthesized via arc-melting and annealing. The antiferromagnetic properties were established through synchrotron measurements of the atom-specific magnetic moments, where the magnetic dichroism reveals large and oppositelyoriented moments on individual V atoms. Density functional theory calculations confirmed the stability of a type G antiferromagnetism involving only two-third of the V atoms, while the remaining V atoms are nonmagnetic. Magnetization, x-ray diffraction and transport measurements also support the antiferromagnetism. This archetypal gapless semiconductor may be considered as a cornerstone for future spintronic devices containing antiferromagnetic elements.

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Electronic structure and magnetism ofFe3−xVxX
Arun Bansil
¹
,
S. Kaprzyk
²
,
P.E. Mijnarends
³

et al.

Cited by 375 publications

References 79 publications

Failure oft−Jmodels in describing doping evolution of spectral weight in x-ray scattering, optical, and photoemission spectra of cuprates

Failure oft−Jmodels in describing doping evolution of spectral weight in x-ray scattering, optical, and photoemission spectra of cuprates

Effect of the tetragonal distortion on the electronic structure, phonons and superconductivity in the Mo3Sb7 superconductor

Antiferromagnetic phase of the gapless semiconductorV3Al

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Electronic structure and magnetism ofFe3−xVxXArun Bansil1, S. Kaprzyk2, P.E. Mijnarends3 et al.

Cited by 375 publications

References 79 publications

Failure oft−Jmodels in describing doping evolution of spectral weight in x-ray scattering, optical, and photoemission spectra of cuprates

Failure oft−Jmodels in describing doping evolution of spectral weight in x-ray scattering, optical, and photoemission spectra of cuprates

Effect of the tetragonal distortion on the electronic structure, phonons and superconductivity in the Mo3Sb7 superconductor

Antiferromagnetic phase of the gapless semiconductorV3Al

Contact Info

Product

Resources

About

Electronic structure and magnetism ofFe3−xVxX
Arun Bansil
¹
,
S. Kaprzyk
²
,
P.E. Mijnarends
³

et al.