Abstract

The authors examine the effect of the core hole on several spectroscopies used to explore the conduction band of simple metals. They show that the static effect on the valence electrons is very strong and discuss under what circumstances this effect may be seen experimentally. In KLV Auger spectra a core hole is present in both initial and final states. Thus, there will be almost no dynamical effect, but the static effect must be accounted for in any quantitative calculation. They present a full effective one-particle calculation for the KL1V and KL2,3V spectra of sodium, that for the first time explain the `mystery' structure seen in experiment, by attributing this effect to the presence of a core hole. The agreement experiment is gratifying although some discrepancy remains. For the main band of soft X-ray emission spectra the core hole is present in the initial state but not in the final state, yet the experimental spectra do not show the strong effect found in KLV. This is explained in terms of the Final State Rule, according to which rather accurate spectra can be obtained from a one-particle calculation provided final-state wave functions are used in the transition matrix elements. The dynamical switching of the core hole potential causes a singular behavior of the X-ray edge, which according to the Final State Rule can be accounted for by multiplicative power-law factors. For the satellite emission band there is an additional core hole in both initial and final states, and, by the Final State Rule, the spectrum should show the static effect of precisely one core hole.(66 refs)