Observation of a Slater-type metal-to-insulator transition in Sr2IrO4 from time-resolved photo-carrier dynamics

Abstract

We perform a time-resolved optical study of Sr2IrO4 to understand the influence of magnetic ordering on the low energy electronic structure of a strongly spin-orbit coupled Jeff=1/2 Mott insulator. By studying the recovery dynamics of photo-carriers excited across the Mott gap, we find that upon cooling through the N\'eel temperature TN the system evolves continuously from a metal-like phase with fast (50 fs) and excitation density independent relaxation dynamics to a gapped phase characterized by slower (500 fs) excitation density dependent bimolecular recombination dynamics. The development of the insulating gap is accompanied by a transfer of in-gap spectral weight to energies far in excess of the gap and occurs over an unusually broad temperature window, which suggests Sr2IrO4 to be a Slater- rather than Mott-Hubbard type insulator and naturally explains the absence of anomalies at TN in transport and thermodynamic measurements.