The Observation of Percolation-Induced 2D Metal-Insulator Transition in a Si MOSFET

Abstract

By analyzing the temperature (T) and density (n) dependence of the measured conductivity (σ) of 2D electrons in the low density (1011cm-2) and temperature (0.02 - 10 K) regime of high-mobility (1.0 and 1.5 × 104 cm2/Vs) Si MOSFETs, we establish that the putative 2D metal-insulator transition is a density-inhomogeneity driven percolation transition where the density-dependent conductivity vanishes as σ (n) (n - np)p, with the exponent p 1.2 being consistent with a percolation transition. The `metallic' behavior of σ (T) for n > np is shown to be well-described by a semi-classical Boltzmann theory, and we observe the standard weak localization-induced negative magnetoresistance behavior, as expected in a normal Fermi liquid, in the metallic phase.