Biexciton-like Auger Blinking in Strongly Confined CsPbBr Perovskite Quantum Dots.

Perovskite quantum dots (QDs) with high room-temperature luminescence efficiency have been applied in single-photon sources. While the optical properties of large, weakly confined perovskite nanocrystals have been extensively explored at the single-particle level, few studies have focused on single-perovskite QDs with strong quantum confinement. This is mainly due to their poor surface chemical stability. Here we demonstrate that strongly confined CsPbBr perovskite QDs (SCPQDs) embedded in a phenethylammonium bromide matrix exhibit a well-passivated surface and improved photostability under intense photoexcitation. We find that in our SCPQDs, photoluminescence blinking is suppressed at moderate excitation intensities, and increasing the excitation rates leads to weak photoluminescence intensity fluctuations accompanied by an unusual spectral blue-shift. We attribute this to a biexciton-like Auger interaction between excitons and trapped excitons formed by surface lattice elastic distortions. This hypothesis is corroborated by the unique repulsive biexciton interaction observed in the SCPQDs.