Final-state effect on x-ray photoelectron spectrum of nominally d1 and n-doped d0 transition metal oxides

Abstract

We investigate the x-ray photoelectron spectroscopy (XPS) of nominally d1 and n-doped d0 transition metal oxides including NbO2, SrVO3, and LaTiO3 (nominally d1), as well as n-doped SrTiO3 (nominally d0). In the case of single phase d1 oxides, we find that the XPS spectra (specifically photoelectrons from Nb 3d, V 2p, Ti 2p core levels) all display at least two, and sometimes three distinct components, which can be consistently identified as d0, d1, and d2 oxidation states (with decreasing order in binding energy). Electron doping increases the d2 component but decreases the d0 component, whereas hole doping reverses this trend; a single d1 peak is never observed, and the d0 peak is always present even in phase-pure samples. In the case of n-doped SrTiO3, the d1 component appears as a weak shoulder with respect to the main d0 peak. We argue that these multiple peaks should be understood as being due to the final-state effect and are intrinsic to the materials. Their presence does not necessarily imply the existence of spatially localized ions of different oxidation states nor of separate phases. A simple model is provided to illustrate this interpretation, and several experiments are discussed accordingly. The key parameter to determine the relative importance between the initial-state and final-state effects is also pointed out.