Abstract
The surface of any binary or multi-component nanocrystal has imperfections and defects. The number of surface defects depends both on the nature of the nanomaterial and on the method of its preparation. One of the possibilities to confine the number of surface defects is the epitaxial growth of the shell, which leads to a change in the physical properties while maintaining the morphology of the core. To form a shell of the desired thickness, an accurate calculation of the amount of its precursors is substantial to avoid the appearance of individual crystals consisting of the shell material. This study aimed to develop an effective calculation method for the theoretical amount of precursors required for the formation of a ZnS shell on the surface of a Cd0.25Zn0.75Se core, followed by the practical implementation of theoretical calculations and characterization of the prepared nanomaterials. This method allows the complete control of the masses and volumes of the initial reagents, which will in turn prevent undesirable nucleation of nuclei consisting of the shell material. In the synthesis of Cd0.25Zn0.75Se/ZnS core/shell quantum dots (QDs), the sources of chalcogens were substituted seleno- and thioureas, which are capable of not only supplanting modern toxic sources of sulfur and selenium but also allowing one to perform the controlled synthesis of highly photoluminescent QDs with a low number of surface defects. The result of this shell overcoating method was an impetuous augmentation in the photoluminescence quantum yield (PL QY up to 83%), uniformity in size and shape, and a high yield of nanomaterials. The developed synthetic technique of core/shell QDs provides a controlled growth of the shell on the core surface, which makes it possible to transfer this method to an industrial scale.
Highlights
Over the past decades, ternary semiconductor quantum dots (QDs) have drawn vast scientific and technological interest due to their unique size, shape, compositiondependent physical, chemical, and optoelectronics properties [1,2,3]
For a more informaFollowing the increase in the number of monolayers on the surface of the core, signifitive presentation, the emission spectra were decomposed into Gaussians
We have presented the employment of an efficient and highly controlled methodology for growing the binary ZnS shell on ternary Cd0.25 Zn0.75 Se quasi-spherical
Summary
Ternary semiconductor quantum dots (QDs) have drawn vast scientific and technological interest due to their unique size-, shape-, compositiondependent physical, chemical, and optoelectronics properties [1,2,3]. CdZnSe QDs have attracted research focus because of the possibility to adjust the compositional Cd:Zn ratio and to tune the emission color over the whole visible spectrum [13,14]. Another successful synthetic strategy for the preparation of highly. Ternary semiconductor QDs suffer from poor stability against the surrounding environment due to the surface defects that act as nonradiative recombination sites [16,17] Such a phenomenon leads to the degradation of PL QY and hinders the actual application of QDs. Growing a mono- or multilayer shell on the QD’s core is one of the effective approaches to solve this problem. Fitzmorris et al [31] introduced a synthetic approach that greatly enhanced the PL QY
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