Abstract
The synthesis of alloyed semiconductor quantum dots has produced structures that have distinct properties in comparison with both their bulk counterparts and their parent binary semiconductor quantum dots. In this work, the quantum confined structures of a ternary alloy of CdSe1−xSx were synthesized by one-pot synthesis method in an aqueous medium at a low temperature and capped with 3-mercaptopropoionic acid. Structures of the synthesized quantum dots were investigated by energy dispersive X-ray, X-ray diffraction, X-ray photoelectron spectroscopy, and high-resolution transmission electron microscopy. The obtained quantum dots had modified cubic structures as proven by X-ray diffraction and selected area electron diffraction. The optical properties of the synthesized quantum dots were characterized by optical absorption, photoluminescence, and color analysis. Optical absorption investigation revealed a widening of the band gap of CdSe1−xSx with increasing S content. This widening increased for the samples suspended in water relative to the samples measured in powder form due to the difference in the environment of the two cases. The size determined from the optical absorption measurements was found to be compatible with the sizes obtained from the X-ray diffraction with the value of bowing parameter around 1, which indicated a graded diffusion of sulfur. It was also ascertained that the emission of different compositions covered the most visible range with a small full width at half maximum. The x and y values of the chromaticity coordinates decreased with increasing sulfur content of up to 15%, while the z value increased.
Highlights
The quantum confined structures of semiconductors have been extensively investigated in the last few decades due to their outstanding physical and chemical properties [1,2]
The absorption maximum and band gap of the prepared quantum dots could be tuned in the visible region by changing the sulfur content
The dependence of the size and band gap were nonlinear with a small bowing constant of 0.2 for low concentrations, which is compatible with that of the bulk materials
Summary
The quantum confined structures of semiconductors have been extensively investigated in the last few decades due to their outstanding physical and chemical properties [1,2]. The tunable physical and optical properties of semiconductor nanostructures can be achieved by two ways: the first by changing the size and dimension of the nanocrystals in the range below the exciton Bohr diameter; and the second is the variation of the optical and physical properties of the nanocrystallite by regulating the constituent stoichiometries of the alloy compounds. In alloying compounds of two binary semiconductors, it is possible to vary the optical and physical properties by changing the constituent composition of the nanostructure This can be carried out by forming ternary semiconductors that are composed of two binary compounds that possess different energy gaps. As a matter of fact, a deeper understanding of CdSSe quantum dots with a highly controllable facile synthesis protocol could meet the demand of future applications
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