English

Variable-range hopping in quasi-one-dimensional electron crystals

Mesoscale and Nanoscale Physics 2007-05-23 v2

Abstract

We study the effect of impurities on the ground state and the low-temperature dc transport in a 1D chain and quasi-1D systems of many parallel chains. We assume that strong interactions impose a short-range periodicicity of the electron positions. The long-range order of such an electron crystal (or equivalently, a 4kF4 k_F charge-density wave) is destroyed by impurities. The 3D array of chains behaves differently at large and at small impurity concentrations NN. At large NN, impurities divide the chains into metallic rods. The low-temperature conductivity is due to the variable-range hopping of electrons between the rods. It obeys the Efros-Shklovskii (ES) law and increases exponentially as NN decreases. When NN is small, the metallic-rod picture of the ground state survives only in the form of rare clusters of atypically short rods. They are the source of low-energy charge excitations. In the bulk the charge excitations are gapped and the electron crystal is pinned collectively. A strongly anisotropic screening of the Coulomb potential produces an unconventional linear in energy Coulomb gap and a new law of the variable-range hopping lnσ(T1/T)2/5-\ln\sigma \sim (T_1 / T)^{2/5}. T1T_1 remains constant over a finite range of impurity concentrations. At smaller NN the 2/5-law is replaced by the Mott law, where the conductivity gets suppressed as NN goes down. Thus, the overall dependence of σ\sigma on NN is nonmonotonic. In 1D, the granular-rod picture and the ES apply at all NN. The conductivity decreases exponentially with NN. Our theory provides a qualitative explanation for the transport in organic charge-density wave compounds.

Keywords

Cite

@article{arxiv.cond-mat/0307299,
  title  = {Variable-range hopping in quasi-one-dimensional electron crystals},
  author = {M. M. Fogler and S. Teber and B. I. Shklovskii},
  journal= {arXiv preprint arXiv:cond-mat/0307299},
  year   = {2007}
}

Comments

20 pages, 7 figures. (v1) The abstract is abridged to 24 lines. For the full abstract, see the manuscript (v2) several changes in presentation per referee's comments. No change in results