Revealing the internal luminescence quantum efficiency of perovskite films via accurate quantification of photon recycling

Abstract

The internal luminescence quantum efficiency (Qilum) provides an excellent assessment of the optoelectronic quality of semiconductors. To determine Qilum of perovskite films from the experimentally accessible external luminescence quantum efficiency (Qelum) it is essential to account for photon recycling, and this requires knowledge of the photon escape probability (pe). Here, we establish an analysis procedure based on a curve fitting model that accurately determines pe of perovskite films from photoluminescence (PL) spectra measured with a confocal microscope and an integrating sphere setup. We show that scattering-induced outcoupling of initially-trapped PL explains commonly observed red-shifted and broadened PL spectral shapes and leads to pe being more than 10% higher in absolute terms compared to earlier assumptions. Applying our model to CH3NH3PbI3 films with exceptionally high Qelum up to 47.4% sets a real benchmark for Qilum at 78.0 0.5\%, revealing there is beyond a factor of two more scope for reducing non-radiative recombination than previously thought.