Probing electronic excitations in iridates with resonant inelastic x-ray scattering and emission spectroscopy techniques

Abstract: We report a comprehensive resonant inelastic x-ray scattering (RIXS) study of various iridate materials focusing on core-level excitations and transitions between crystal-field split d-levels. The 2p core hole created at the Ir $L_3$ absorption edge has a very short lifetime giving rise to a broad absorption width ($\sim 5$~eV). This absorption linewidth broadening can be overcome by studying the resonant x-ray emission spectroscopy (RXES) map, which is a two-dimensional intensity map of the Ir L$\alpha_2$ emission obtained with high energy-resolution monochromator and analyzer. By limiting the emitted photon energy to a narrow range, one can obtain x-ray absorption spectra in the high energy-resolution fluorescence detection (HERFD) mode, while one can also simulate quasi-$M_4$-edge absorption spectra by integrating over incident photon energies. Both methods improve the absorption line width significantly, allowing detailed studies of unoccupied electronic structure in iridates and other $5d$ transition metal compounds. On the other hand, the short lifetime of the 2p core hole benefits the study of excitations of valence electrons. We show that the incident energy dependence of the RIXS spectra for $d-d$ transitions is simple to understand due to the short core-hole lifetime, which validates ultra-short core-hole lifetime approximation used widely in theoretical calculations. We compared $d-d$ excitations in various iridates and found that the excitations between the t${2g}$ and e$_g$ states share many similarities among different materials. However, the RIXS spectra due to the transitions between the spin-orbit-split t${2g}$ levels vary widely depending on the oxidation state and electronic bandwidths.