Persistent current and Drude weight for the one-dimensional Hubbard model from current lattice density functional theory

Citation

A. Akande and S. Sanvito, Persistent current and Drude weight for the one-dimensional Hubbard model from current lattice density functional theory, Journal of Physics: Condensed Matter, 24, 5, 055602, 2012

Abstract

The Bethe ansatz local density approximation (LDA) to lattice density functional theory (LDFT) for the one-dimensional repulsive Hubbard model is extended to current-LDFT (CLDFT). The transport properties of mesoscopic Hubbard rings threaded by a magnetic flux are then systematically investigated by this scheme. In particular we present calculations of ground state energies, persistent currents and Drude weights for both a repulsive homogeneous and a single impurity Hubbard model. Our results for the ground state energies in the metallic phase compare favorably well with those obtained with numerically accurate many-body techniques. Also the dependence of the persistent currents on the Coulomb and the impurity interaction strength, and on the ring size are all well captured by LDA-CLDFT. Our study demonstrates the value of CLDFT in describing the transport properties of one-dimensional correlated electron systems. As its computational overheads are rather modest, we propose this method as a tool for studying problems where both disorder and interaction are present.

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Sponsor: Science Foundation Ireland (SFI)
Grant Number: SFI05/RFP/PHY0062

Sponsor: Science Foundation Ireland (SFI)
Grant Number: 07/IN.1/I945

Type of material: Journal Article