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Abstract
Density functional theory electronic structures, maximally localized Wannier funcitons and linear response theory are used to compute the electron and hole mobility of both inorganic, Cs-containing, and hybrid, CH3NH3-containing, lead bromide perovskites. When only phonon scattering is considered we find hole mobilities at room temperature in the 40-180~cm2V-1s-1 range, in good agreement with experimental data for highly-ordered crystals. The electron mobility is about an order of magnitude larger, because low-energy phonons are ineffective over the Pb 6p shell. Most importantly, our parameter-free approach, finds a T-3/2 power-law temperature dependence of the mobility, which is a strong indication of polaronic transport. Our work then offers an independent theoretical validation of the many hypotheses about the polaronic nature of the charge carriers in lead halide perovskites.
