Narrowing the photoluminescence bandwidth of InP‐based colloidal quantum dots through photon‐triggered isolation

Abstract

AbstractThe optimization of photoluminescence (PL) spectral bandwidths in InP‐based colloidal quantum dots (QDs) faces limitations with traditional synthetic methods. This study introduces a novel approach utilizing light‐induced thiolate ligand detachment to selectively precipitate QDs within an ensemble, triggered by photons whose energy matches the red tail of the band‐edge absorption peak. We demonstrate that incorporating benzoquinone as an electron acceptor under inert conditions crucially enhances the efficiency of photoexcited hole‐induced ligand detachment. Through careful optimization of laser exposure conditions, we successfully narrowed the PL bandwidth of InP/ZnSe/ZnS QDs from 39 to 35 nm. Our findings offer significant insights into the development of high‐performance QD‐based displays, promising advancements in color purity.