Resistivity and optical conductivity of cuprates within the t-J model

Abstract

The optical conductivity σ(ω) and the d.c. resistivity (T) within the extended t-J model on a square lattice, as relevant to high-Tc cuprates, are reinvestigated using the exact-diagonalization method for small systems, improved by performing a twisted boundary condition averaging. The influence of the next-nearest-neighbor hopping t' is also considered. The behaviour of results at intermediate doping is consistent with a marginal-Fermi-liquid scenario and in the case of t'=0 for ω>T follows the power law σ ω- with 0.65 consistent with experiments. At low doping ch<0.1 for T<J σ(ω) develops a shoulder at ω ω*, consistent with the observed mid-infrared peak in experiments, accompanied by a shallow dip for ω < ω*. This region is characterized by the resistivity saturation, whereas a more coherent transport appears at T < T* producing a more pronounced decrease in (T). The behavior of the normalized resistivity ch (T) is within a factor of 2 quantitatively consistent with experiments in cuprates.

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