Evidence for a correlated insulator to antiferromagnetic metal transition in CrN

Abstract

We investigate the electronic structure of Chromium Nitride (CrN) across the first-order magneto-structural transition at TN ~ 286 K. Resonant photoemission spectroscopy shows a gap in the 3d partial density of states at the Fermi level and an On-site Coulomb energy U ~ 4.5 eV, indicating strong electron-electron correlations. Bulk-sensitive high resolution (6 meV) laser photoemission reveals a clear Fermi edge indicating an antiferromagnetic metal below TN. Hard x-ray Cr 2p core-level spectra show T-dependent changes across TN which originate from screening due to coherent states as substantiated by cluster model calculations using the experimentally observed U. The electrical resistivity confirms an insulator above TN (Eg ~ 70 meV) which becomes a disordered metal below TN. The results indicate CrN transforms from a correlated insulator to an antiferromagnetic metal, coupled to the magneto-structural transition.