Low-energy peak in the one-particle spectral function of the electron gas at metallic densities
Abstract
Based on a nonperturbative scheme to determine the self-energy (k,iwn) with automatically satisfying the Ward identity and the total momentum conservation law, a fully self-consistent calculation is done in the electron gas at various temperatures T to obtain G(k,iwn) the one-particle Green's function with fulfilling all known conservation laws, sum rules, and correct asymptotic behaviors; here, T is taken unprecedentedly low, namely, T/EF down to 10-4 with EF the Fermi energy, and tiny mesh as small as 10-4kF is chosen near the Fermi surface in k space with kF the Fermi momentum. By analytically continuing G(k,iwn) to the retarded function GR(k,w), we find a novel low-energy peak, in addition to the quasiparticle (QP) peak and one- and two-plasmon high-energy satellites, in the spectral function A(k,w)[= -Im GR(k,w)/π] for T less than about 10-3EF in the simple-metal density region (2<rs<6 with rs the dimensionless density parameter). This new peak is attributed to the effect of excitonic attraction on (k,iwn) arising from multiple excitations of tightly bound electron-hole pairs in the polarization function (q,iwq) for |q| equal to about 2kF and |wq| << EF and thus it is dubbed ``excitron''. Although this excitron peak height is only about a one-hundredth of that of QP, its excitation energy is about a half of that of QP for |k| equal to about kF, seemingly in contradiction to the Landau's hypothesis as to the one-to-one correspondence of low-energy excitations between a free Fermi gas and an interacting normal Fermi liquid. As for the QP properties, our results of both the effective mass m* and the renormalization factor z* are in good agreement with those provided by recent quantum Monte Carlo simulations and available experiments.
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