The photon absorption edge in superconductors and gapped 1D systems

Abstract

Opening of a gap in the low-energy excitations spectrum affects the power-law singularity in the photon absorption spectrum A(). In the normal state, the singularity, A() [D/(- th)]α, is characterized by an interaction-dependent exponent α. On the contrary, in the supeconducting state the divergence, A() (D/)α(- th)-1/2, is interaction-independent, while threshold is shifted, th= th+; the ``normal-metal'' form of A() resumes at (- th) (1/α). If the core hole is magnetic, it creates in-gap states; these states transform drastically the absorption edge. In addition, processes of scattering off the magnetic core hole involving spin-flip give rise to inelastic absorption with one or several real excited pairs in the final state, yielding a structure of peaks in A() at multiples of 2 above the threshold frequency. The above conclusions apply to a broad class of systems, e.g., Mott insulators, where a gap opens at the Fermi level due to the interactions.