Fermi-edge singularity in the vicinity of the resonant scattering condition

Abstract

Fermi-edge absorption theory predicting the spectrum, A(ω) ω-2δ0/π+δ20/π2, relies on the assumption that scattering phase, δ0, is frequency-independent. Dependence of δ0 on ω becomes crucial near the resonant condition, where the phase changes abruptly by π. In this limit, due to finite time spent by electron on a resonant level, the scattering is dynamic. We incorporate this time delay into the theory, solve the Dyson equation with a modified kernel and find that, near the resonance, A(ω) behaves as ω-3/4 | ω|. Resonant scattering off the core hole takes place in 1D and 2D in the presence of an empty subband above the Fermi level; then attraction to hole splits off a resonant level from the bottom of the empty subband. Fermi-edge absorption in the regime when resonant level transforms into a Kondo peak is discussed.