Deciphering exciton-generation processes in quantum-dot electroluminescence

Abstract: Electroluminescence (EL) of colloidal nanocrystals promises a new generation of high-performance and solution-processable light-emitting diodes (LEDs). The operation of nanocrystal-based LEDs relies on the recombination of electrically-generated excitons. However, a fundamental question, i.e, how excitons are electrically generated in individual nanocrystals, remains unanswered. Here, we reveal a molecular mechanism of sequential electron-hole injection for the exciton generation in nanocrystal-based EL devices. To decipher the corresponding elementary processes, we develop electrically-pumped single-nanocrystal spectroscopy. While hole injection into neutral quantum dots (QDs) is generally-considered to be inefficient, we find that the intermediate negatively-charged state of QD triggers confinement-enhanced Coulomb interactions, which simultaneously accelerate hole injection and hinder excessive electron injection. In-situ/operando spectroscopy on state-of-the-art QD-LEDs demonstrate that exciton generation at the ensemble level is consistent with the charge-confinement-enabled sequential electron-hole injection mechanism revealed at the single-nanocrystal level. Our findings provide a universal mechanism for enhancing charge balance in nanocrystal-based EL devices.