T. Micklitz, A. Levchenko, A. Rosch
Published 2012-02-21, updated 2012-08-07Version 2
We calculate the linear and nonlinear conductance of spinless fermions in clean, long quantum wires where short-ranged interactions lead locally to equilibration. Close to the quantum phase transition where the conductance jumps from zero to one conductance quantum, the conductance obtains an universal form governed by the ratios of temperature, bias voltage and gate voltage. Asymptotic analytic results are compared to solutions of a Boltzmann equation which includes the effects of three-particle scattering. Surprisingly, we find that for long wires the voltage predominantly drops close to one end of the quantum wire due to a thermoelectric effect.
Comments: 4+ pages, 3 figures plus supplementary material (2 pages, 1 figure); minor changes, references corrected
Journal: Phys. Rev. Lett. 109, 036405 (2012)
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