Electron-phonon interactions in transition metal oxides in the framework of DFT+$U$.

First-principles approaches enable accurate calculations of electron-phonon ($e$-ph) interactions in a wide range of solids. However, in many transition metal oxides (TMOs) computing $e$-ph interactions remains challenging due to large self-interaction errors for localized $d$ electrons. Here we show calculations of $e$-ph interactions in the framework of Hubbard-$U$ corrected density functional theory (DFT+$U$) and its linear response extension (DFPT+$U$), which can accurately describe the electronic structure and lattice dynamics in TMOs. We investigate the $e$-ph coupling and electron spectral functions in CoO, a prototypical TMO, employing a Hubbard $U$ parameter computed \textit{ab initio}. While standard DFPT $e$-ph calculations lead to short-ranged and unphysically divergent $e$-ph interactions, DFPT+$U$ removes the divergences and properly accounts for the long-range Fr\"ohlich interaction. We show that in CoO the Hubbard $U$-derived $e$-ph perturbation acts primarily on the partially filled $d$ bands, and that restoring the Fr\"ohlich interaction with DFPT+$U$ enables studies of polarons in TMOs. Our results demonstrate the crucial effects of the Hubbard $U$ correction on $e$-ph interactions, highlighting the interplay of electron, spin and lattice degrees of freedom in TMOs.