Electron transmission through a short interacting wire: 0.7 conductance anomaly
Abstract
We investigate tunneling through a short interacting wire. We identify two temperature regimes (a) TKondo<T Twire= vF/kBd (d is the length of the short wire) and (b) T<TKondo Twire. In the first regime the effective (renormalized) electron-electron interaction is smaller than the tunneling matrix element. This is the situation at finite temperature T where the single particle spectrum of the wire is characterized by a multilevel "quantum dot" system with magnetic quantum number S=0 which is higher in energy than the SU(2) spin doublet S=1/2. Due to the single particle energy we find that the tunneling electron into the wire must have an opposite spin to the one in the short wire giving rise to a conductance, G= G+G, e2/h G 2e2/h. In the second regime, when T 0 we have a situation that the effective (renormalized) electron-electron interaction is larger than the tunneling matrix element. This problem is equivalent to a Kondo problem. We find for T<TKondo that the conductance is given by G=2e2/h. These results are in agreement with recent experiments where for TKondo<T<Twire the conductance G obeys e2/h G 2e2/h, and for T< TKondo, G=2e2/h. In both regimes the current is not polarized and the SU(2) symmetry is not broken.
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