Synthesis and Size-Dependent Optical Properties of CdP and (CdZn)P Quantum Dots.

Short-wave infrared (SWIR) materials are highly beneficial in telecommunications and medical imaging. Synthesis of quality SWIR chromophores remains challenging. Furthermore, many SWIR-emitting colloidal quantum dots (QDs) suffer from long radiative lifetimes and weak emission efficiencies. To address these challenges, we present methods to create a size series of CdP QDs and create a sizing curve. The results demonstrate that the growth kinetics and the production of CdP QDs with optical emission at 1.5+ μm are limited by the precursor stoichiometry. To address the overly long radiative lifetimes, we develop surface passivation with CdI and develop a one-pot, hot-injection synthesis of (CdZn)P QDs, which is shown to accelerate the PL dynamics of CdP QDs. Electron microscopy and elemental analysis point to the CdP/(CdZn)P core/crust structure of these QDs. These results show promise for the further development of core/shell CdP/ZnP QDs, which will serve as on-demand single-photon emitters in the SWIR region.