Metal-insulator transition at B=0 in an ultra-low density (rs=23) two dimensional GaAs/AlGaAs hole gas

Abstract

We have observed a metal-insulator transition in an ultra-low density two dimensional hole gas formed in a high quality GaAs-AlGaAs heterostructure at B=0. At the highest carrier density studied (ps=2.2x1010 cm-2, rs=16) the hole gas is strongly metallic, with an exceptional mobility of 425,000 cm2V-1s-1. The low disorder and strength of the many-body interactions in this sample are highlighted by the observation of re-entrant metal insulator transitions in both the fractional ( < 1/3) and integer (2 > > 1) quantum Hall regimes. On reducing the carrier density the temperature and electric field dependence of the resistivity show that the sample is still metallic at ps=1.3x1010 cm-2 (rs=21), becoming insulating at ps1x1010 cm-2. Our results indicate that electron-electron interactions are dominant at these low densities, pointing to the many body origins of this metal-insulator transition. We note that the value of rs at the transition (rs=23 +/- 2) is large enough to allow the formation of a weakly pinned Wigner crystal, and is approaching the value calculated for the condensation of a pure Wigner crystal.

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