Correlation of the Atomic Structure and Photoluminescence of the Same Colloidal Quantum Dot
Orfield, Noah Jeremiah
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2015-11-16
Abstract
Colloidal quantum dots (QDs) promise to revolutionize light harvesting for photovoltaics and controlled light emission from devices such as LEDs, lasers, and even nanometer-scale single-QD optical switches and routers. Extremely large extinction coefficients, precisely tunable optical properties, and the robust inorganic nature of these QDs make them excellent light absorbers; however, control over charge separation and exciton recombination has proven extremely challenging to achieve, both on the single-QD and ensemble scales. Furthermore, inherent heterogeneity in the shape, size, and morphology of core/shell QDs results in a distribution of expressed optical behaviors due to the interplay of the physical structure and electronic structure of the QD. Broadened ensemble photoluminescence linewidths and absorption spectra, varying radiative and nonradiative recombination rates of the exciton, and charge trapping rates all depend on the morphology of each individual QD. In this work, a correlative imaging technique was developed to allow complete investigation of physical properties (precise atomic structure, shape, size, and spatially-resolved chemical composition) and photoluminescence behavior (quantum yield, radiative decay lifetime, biexciton quantum yield, and blinking statistics) of single QDs. This simple, unambiguous correlation strategy provides a means for investigating structure-function relationships for single QDs. Implementation of the correlation technique allowed deleterious optical properties to be correlated with structural defects in a commercially available and well-studied QD system. Use of the technique also facilitated discovery of quantum yield heterogeneity among nonblinking “giant” CdSe/CdS core/shell QDs—an unexpected finding that explains the reduced photoluminescence quantum yield observed on the ensemble level for this QD system. Finally, the utility of this technique as a helpful feedback generator in the synthetic refinement processes for QDs and other nanostructured systems is discussed.