Colloidal Quantum Dot Infrared Lasers Featuring Sub-Single-Exciton Threshold and Very High Gain.

Abstract

The use of colloidal quantum dots (CQDs) as a gain medium in infrared laser devices has been underpinned by the need for high pumping intensities, very short gain lifetimes, and low gain coefficients. Here, PbS/PbSSe core/alloyed-shell CQDs are employed as an infrared gain medium that results in highly suppressed Auger recombination with a lifetime of 485ps, lowering the amplified spontaneous emission (ASE) threshold down to 300µJcm-2 , and showing a record high net modal gain coefficient of 2180cm-1 . By doping these engineered core/shell CQDs up to nearly filling the first excited state, a significant reduction of optical gain threshold is demonstrated, measured by transient absorption, to an average-exciton population-per-dot 〈Nth 〉g of 0.45due to bleaching of the ground state absorption. This in turn have led to a fivefold reduction in ASE threshold at 〈Nth 〉ASE =0.70excitons-per-dot, associated with a gain lifetime of 280ps. Finally, these heterostructured QDs are used to achieve near-infrared lasing at 1670nm at a pump fluences corresponding to sub-single-exciton-per-dot threshold (〈Nth 〉Las =0.87). This work brings infrared CQD lasing thresholds on par to their visible counterparts, and paves the way toward solution-processed infrared laser diodes.