When Blinking Helps: Suppressed Biexciton Emission in Lead Halide Perovskite Quantum Dots

Abstract

Blinking and multiphoton emission in metal halide perovskite quantum dots (PQDs) limit their use as single-photon quantum emitters. Conventional models distinguish between trion-related A-type blinking and defect-assisted BC-type blinking, both expected to degrade single-photon purity in a dark state. Here, time-resolved spectroscopy on individual PQDs reveals a qualitatively different regime in which low emitting dark states exhibit higher single-photon purity than bright states. For those PQDs state-resolved g(2)(τ) analysis shows that the exciton photoluminescence quantum yield decreases by a factor of 8, while the biexciton one is suppressed by a factor of 10. This leads to a moderate improvement of single-photon purity with g(2)0 decreased from 0.155 to 0.120. In contrast, PQDs with fluorescence lifetime--intensity distribution patterns characteristic for A-type blinking, display the expected increase of g(2)0 in charged, trion-dominated states. To explain the observed improvement of single-photon purity of low-emitting dark states, we propose a self-trapped-exciton (STE) mechanism that selectively blocks biexciton formation by diverting hot excitons into long-lived, weakly emissive STE configurations. This STE-mediated blinking channel explains why certain low-emitting states improve, rather than degrade, single-photon purity and suggests a lattice-driven route to perovskite quantum emitters with intrinsically suppressed multiphoton events.