First-Principles Effective Mass in the Three-Dimensional Uniform Electron Gas

Abstract

The quasiparticle effective mass m* of the three-dimensional uniform electron gas (UEG) is a fundamental Fermi-liquid parameter whose value and density dependence have remained controversial for decades. Using renormalized perturbation theory with explicit counterterms, we determine m* in the metallic regime (rs 6) from first principles by two complementary routes -- the self-energy and the forward-scattering four-point vertex via the p-wave spin-symmetric Landau parameter F1s -- that agree within uncertainties at each density through sixth renormalized order. The resulting m*/m remains close to unity throughout the metallic regime, with a shallow non-monotonic density dependence -- a minimum near rs≈ 1 followed by a gentle upturn -- reflecting the interplay of exchange and dynamical screening in the self-energy, and disfavoring strong monotonic suppression. This finding supports a physical picture for the metallic UEG in which dominant charge correlations are concentrated in nearly forward scattering and generate only a weak F1s component.