Fig. 1: The light was incident on the Cu(001) crystal surface at a grazing angle. The axis of the analyser transfer lenses lies in a plane perpendicular to the incident light and at an angle of 90° to each other. The energy dispersing directions are marked E1 and E2, respectively.

The absorption of a single photon by an electronic system and subsequent electron pair emission is called double photoemission (DPE). A finite DPE intensity requires a finite electron-electron interaction. We have demonstrated that it is possible to probe the exchange-correlation hole in a similar way as in the electron excited pair emission [1-3]. A particular DPE process concerns the emission of a core photoelectron and the subsequent decay via Auger electron emission. The Auger effect is usually explained via a two-step process in which a core electron is ejected followed by a de-excitation via Auger electron emission. We provide the first experimental proof that the core-electron and Auger electron emission proceeds via a single step [4].  By using two hemispherical analyzers (Fig. 1), it is possible to map out the energy distribution of correlated electron pairs emitted from the valence band by direct DPE and, simultaniously, of pairs emitted from the processes of core-level photoemission and Auger decay.  Fig. 2 shows the number of electron pairs detected for each combination of individual electron kinetic energies EA and EB.