English

Coulomb drag between two-dimensional electron systems

Condensed Matter 2009-10-22 v1

Abstract

The Coulomb contribution to the temperature-dependent rate of momentum transfer, 1/τD1/\tau_D, between two electron systems in parallel layers is determined by setting up two coupled Boltzmann equations, with the boundary condition that no current flows in the layer where an induced voltage is measured. The effective Coulomb interaction between the layers is determined selfconsistently, allowing for the finite thickness of the layers. As T0T\rightarrow 0, we find that 1/τDT21/\tau_DT^2 approaches a constant value. At higher temperatures 1/τDT21/\tau_DT^2 exhibits a maximum at T=TmaxT=T_{\rm max} and then decreases as 1/T1/T with increasing temperature. The value of TmaxT_{\rm max} depends on the layer separation dd according to TmaxdαT_{\rm max}\propto d^{-\alpha}, where α0.8\alpha\simeq 0.8. The overall magnitude of the calculated 1/τD1/\tau_D is approximately one half of the results of a recent experiment, suggesting that other mechanisms of momentum transfer may be important.

Keywords

Cite

@article{arxiv.cond-mat/9205001,
  title  = {Coulomb drag between two-dimensional electron systems},
  author = {Antti-Pekka Jauho and Henrik Smith},
  journal= {arXiv preprint arXiv:cond-mat/9205001},
  year   = {2009}
}

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12 pages