Drude weight of the two-dimensional Hubbard model - Reexamination of finite-size effect in exact diagonalization study

Hiroki Nakano; Yoshinori Takahashi; Masatoshi Imada

doi:10.1143/JPSJ.76.034705

Drude weight of the two-dimensional Hubbard model - Reexamination of finite-size effect in exact diagonalization study

Hiroki Nakano^*, Yoshinori Takahashi, Masatoshi Imada

^*Corresponding author for this work

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

15 Citations (Scopus)

Abstract

The Drude weight of the Hubbard model on the two-dimensional square lattice is studied by the exact diagonalizations applied to clusters up to 20 sites. We carefully examine finite-size effects by consideration of the appropriate shapes of clusters and the appropriate boundary condition beyond the limitation of employing only the simple periodic boundary condition. We successfully capture the behavior of the Drude weight that is proportional to the squared hole doping concentration. Our present result gives a consistent understanding of the transition between the Mott insulator and doped metals. We also find, in the frequency dependence of the optical conductivity, that the mid-gap incoherent part emerges more quickly than the coherent part and rather insensitive to the doping concentration in accordance with the scaling of the Drude weight.

Original language	English
Article number	034705
Journal	journal of the physical society of japan
Volume	76
Issue number	3
DOIs	https://doi.org/10.1143/JPSJ.76.034705
Publication status	Published - 2007 Mar
Externally published	Yes

Keywords

Drude weight
Hubbard model
Lanczos method
Metal-insulator transition
Optical conductivity

ASJC Scopus subject areas

Physics and Astronomy(all)

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10.1143/JPSJ.76.034705

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title = "Drude weight of the two-dimensional Hubbard model - Reexamination of finite-size effect in exact diagonalization study",

abstract = "The Drude weight of the Hubbard model on the two-dimensional square lattice is studied by the exact diagonalizations applied to clusters up to 20 sites. We carefully examine finite-size effects by consideration of the appropriate shapes of clusters and the appropriate boundary condition beyond the limitation of employing only the simple periodic boundary condition. We successfully capture the behavior of the Drude weight that is proportional to the squared hole doping concentration. Our present result gives a consistent understanding of the transition between the Mott insulator and doped metals. We also find, in the frequency dependence of the optical conductivity, that the mid-gap incoherent part emerges more quickly than the coherent part and rather insensitive to the doping concentration in accordance with the scaling of the Drude weight.",

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AU - Nakano, Hiroki

AU - Takahashi, Yoshinori

AU - Imada, Masatoshi

PY - 2007/3

Y1 - 2007/3

N2 - The Drude weight of the Hubbard model on the two-dimensional square lattice is studied by the exact diagonalizations applied to clusters up to 20 sites. We carefully examine finite-size effects by consideration of the appropriate shapes of clusters and the appropriate boundary condition beyond the limitation of employing only the simple periodic boundary condition. We successfully capture the behavior of the Drude weight that is proportional to the squared hole doping concentration. Our present result gives a consistent understanding of the transition between the Mott insulator and doped metals. We also find, in the frequency dependence of the optical conductivity, that the mid-gap incoherent part emerges more quickly than the coherent part and rather insensitive to the doping concentration in accordance with the scaling of the Drude weight.

AB - The Drude weight of the Hubbard model on the two-dimensional square lattice is studied by the exact diagonalizations applied to clusters up to 20 sites. We carefully examine finite-size effects by consideration of the appropriate shapes of clusters and the appropriate boundary condition beyond the limitation of employing only the simple periodic boundary condition. We successfully capture the behavior of the Drude weight that is proportional to the squared hole doping concentration. Our present result gives a consistent understanding of the transition between the Mott insulator and doped metals. We also find, in the frequency dependence of the optical conductivity, that the mid-gap incoherent part emerges more quickly than the coherent part and rather insensitive to the doping concentration in accordance with the scaling of the Drude weight.

KW - Drude weight

KW - Hubbard model

KW - Lanczos method

KW - Metal-insulator transition

KW - Optical conductivity

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Drude weight of the two-dimensional Hubbard model - Reexamination of finite-size effect in exact diagonalization study

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Keywords

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