Electron-electron interaction effects in quantum point contacts
Abstract
We consider electron-electron interaction effects in quantum point contacts on the first quantization plateau, taking into account all scattering processes. We compute the low-temperature linear and nonlinear conductance, shot noise, and thermopower, by perturbation theory and a self-consistent nonperturbative method. On the conductance plateau, the low-temperature corrections are solely due to momentum-nonconserving processes that change the relative number of left- and right-moving electrons. This leads to a suppression of the conductance for increasing temperature or voltage. The size of the suppression is estimated for a realistic saddle-point potential, and is largest in the beginning of the conductance plateau. For large magnetic field, interaction effects are strongly suppressed by the Pauli principle, and hence the first spin-split conductance plateau has a much weaker interaction correction. For the nonperturbative calculations, we use a self-consistent nonequilibrium Green's function approach, which suggests that the conductance saturates at elevated temperatures. These results are consistent with many experimental observations related to the so-called 0.7 anomaly.
Cite
@article{arxiv.0901.1183,
title = {Electron-electron interaction effects in quantum point contacts},
author = {A. M. Lunde and A. De Martino and A. Schulz and R. Egger and K. Flensberg},
journal= {arXiv preprint arXiv:0901.1183},
year = {2009}
}
Comments
29 pages, New Journal of Physics, in press