Nematic metal in a multi-valley electron gas: Variational Monte Carlo analysis and application to AlAs

Abstract

The two-dimensional electron gas is of fundamental importance in quantum many-body physics. We study a minimal extension of this model with C4 (as opposed to full rotational) symmetry and an electronic dispersion with two valleys with anisotropic effective masses. Using variational Monte Carlo simulations, we find a broad intermediate range of densities with a metallic valley-polarized, spin-unpolarized ground-state. Our results are of direct relevance to the recently discovered ``nematic'' state in AlAs quantum wells. For the effective mass anisotropy relevant to this system, mx/my≈ 5.2, we obtain a transition from an anisotropic metal to a valley-polarized metal at rs ≈ 12 (where rs is the dimensionless Wigner-Seitz radius). At still lower densities, we find a (possibly metastable) valley and spin-polarized state with a reduced electronic anisotropy.