Temperature-Dependence of Magnetically-Active Charge Excitations in Magnetite across the Verwey Transition

Abstract

We have studied the electronic structure of bulk single crystals and epitaxial films of magnetite Fe3O4. Fe 2p core-level spectra show clear differences between hard x-ray (HAX-) and soft x-ray (SX-) photoemission spectroscopy (PES), indicative of surface effects. The bulk-sensitive spectra exhibit temperature (T)-dependent charge excitations across the Verwey transition at TV=122 K, which is missing in the surface-sensitive spectra. An extended impurity Anderson model full-multiplet analysis reveals roles of the three distinct Fe-species (A-Fe3+, B-Fe2+, B-Fe3+) below TV for the Fe 2p spectra, and its T-dependent evolution. The Fe 2p HAXPES spectra show a clear magnetic circular dichroism (MCD) in the metallic phase of magnetized 100-nm-thick films. The model calculations also reproduce the MCD and identify the magnetically distinct sites associated with the charge excitations. Valence band HAXPES shows finite density of states at EF for the polaronic metal with remnant order above TV, and a clear gap formation below TV. The results indicate that the Verwey transition is driven by changes in the strongly correlated and magnetically active B-Fe2+ and B-Fe3+ electronic states, consistent with resistivity and bulk-sensitive optical spectra.