Charge excitations in NaV2O5

A. Hübsch; C. Waidacher; K. W. Becker; W. von der Linden

doi:10.1103/PhysRevB.64.075107

Charge excitations in NaV2O5

A. Hübsch, C. Waidacher, K. W. Becker, W. von der Linden

Working Group Many Body Physics (5154)

Research output: Contribution to journal › Article › peer-review

Abstract

We calculate the electron-energy loss spectrum and the optical conductivity for NaV2O5 using the standard Lanczos algorithm. The vanadium ions in NaV2O5 form a system of coupled ladders that can be described by a quarter-filled extended Hubbard model. Since this system has a large unit cell, one has to be very careful to avoid finite-size effects in the calculations. We show this by performing exact diagonalization of different clusters with up to 16 sites. The calculated loss function for the extended Hubbard model shows good agreement with experimental spectra. Furthermore, a qualitative description of the optical conductivity is obtained with the same Hamiltonian, and the same set of model parameters. The comparison with the experiment shows that interladder hopping is of minor importance for a realistic description of charge excitations in NaV2O5. We find that the character of the excitations depends strongly on the direction of momentum transfer.

Original language	English
Article number	075107
Number of pages	7
Journal	Physical Review B
Volume	64
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevB.64.075107 https://doi.org/10.1103/PhysRevB.64.075107
Publication status	Published - 2001

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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title = "Charge excitations in NaV2O5",

abstract = "We calculate the electron-energy loss spectrum and the optical conductivity for NaV2O5 using the standard Lanczos algorithm. The vanadium ions in NaV2O5 form a system of coupled ladders that can be described by a quarter-filled extended Hubbard model. Since this system has a large unit cell, one has to be very careful to avoid finite-size effects in the calculations. We show this by performing exact diagonalization of different clusters with up to 16 sites. The calculated loss function for the extended Hubbard model shows good agreement with experimental spectra. Furthermore, a qualitative description of the optical conductivity is obtained with the same Hamiltonian, and the same set of model parameters. The comparison with the experiment shows that interladder hopping is of minor importance for a realistic description of charge excitations in NaV2O5. We find that the character of the excitations depends strongly on the direction of momentum transfer.",

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T1 - Charge excitations in NaV2O5

AU - Hübsch, A.

AU - Waidacher, C.

AU - Becker, K. W.

AU - von der Linden, W.

PY - 2001

Y1 - 2001

N2 - We calculate the electron-energy loss spectrum and the optical conductivity for NaV2O5 using the standard Lanczos algorithm. The vanadium ions in NaV2O5 form a system of coupled ladders that can be described by a quarter-filled extended Hubbard model. Since this system has a large unit cell, one has to be very careful to avoid finite-size effects in the calculations. We show this by performing exact diagonalization of different clusters with up to 16 sites. The calculated loss function for the extended Hubbard model shows good agreement with experimental spectra. Furthermore, a qualitative description of the optical conductivity is obtained with the same Hamiltonian, and the same set of model parameters. The comparison with the experiment shows that interladder hopping is of minor importance for a realistic description of charge excitations in NaV2O5. We find that the character of the excitations depends strongly on the direction of momentum transfer.

AB - We calculate the electron-energy loss spectrum and the optical conductivity for NaV2O5 using the standard Lanczos algorithm. The vanadium ions in NaV2O5 form a system of coupled ladders that can be described by a quarter-filled extended Hubbard model. Since this system has a large unit cell, one has to be very careful to avoid finite-size effects in the calculations. We show this by performing exact diagonalization of different clusters with up to 16 sites. The calculated loss function for the extended Hubbard model shows good agreement with experimental spectra. Furthermore, a qualitative description of the optical conductivity is obtained with the same Hamiltonian, and the same set of model parameters. The comparison with the experiment shows that interladder hopping is of minor importance for a realistic description of charge excitations in NaV2O5. We find that the character of the excitations depends strongly on the direction of momentum transfer.

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DO - 10.1103/PhysRevB.64.075107

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Charge excitations in NaV2O5

Abstract

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