Coulomb Drag between Quantum Wires
摘要
We study Coulomb drag in a pair of parallel one-dimensional electron systems within the framework of the Tomanaga-Luttinger model. We find that Coulomb coupling has a much stronger effect on one dimensional wires than on two-dimensional layers: At zero temperature the trans-resistivity {\em diverges}, due to the formation of locked charge density waves. At temperature well above a cross-over temperature the trans-resistivity follows a power law , where the interaction-strength dependent exponent is determined by the Luttinger Liquid parameter of the relative charge mode. At temperature below relative charge displacements are enabled by solitonic excitations, reflected by an exponential temperature dependence. The cross-over temperature depends sensitively on the wire width, inter-wire distance, Fermi wavelength and the effective Bohr radius. For wire distances it is exponentially suppressed with . The behavior changes drastically if each of the two wires develop spin gaps. In this case we find that the trans-resistivity {\em vanishes} at zero temperature. We discuss our results in view of possible experimental realizations in GaAs-AlGaAs semiconductor structures.
引用
@article{arxiv.cond-mat/9912371,
title = {Coulomb Drag between Quantum Wires},
author = {Rochus Klesse and Ady Stern},
journal= {arXiv preprint arXiv:cond-mat/9912371},
year = {2009}
}
备注
16 pages, 3 figures, revTeX