Electronic Absorption Spectroscopy of Cobalt Ions in Diluted Magnetic Semiconductor Quantum Dots: Demonstration of an Isocrystalline Core/Shell Synthetic Method

Abstract

This paper reports the application of ligand-field electronic absorption spectroscopy to probe Co²⁺ dopant ions in diluted magnetic semiconductor quantum dots. It is found that standard inverted micelle coprecipitation methods for preparing Co²⁺-doped CdS (Co²⁺:CdS) quantum dots yield dopant ions predominantly bound to the nanocrystal surfaces. These Co²⁺:CdS nanocrystals are unstable with respect to solvation of surface-bound Co²⁺, and time-dependent absorption measurements allow identification of two transient surface-bound intermediates involving solvent−cobalt coordination. Comparison with Co²⁺:ZnS quantum dots prepared by the same methods, which show nearly isotropic dopant distribution, indicates that the large mismatch between the ionic radii of Co²⁺ (0.74 Å) and Cd²⁺ (0.97 Å) is responsible for exclusion of Co²⁺ ions during CdS nanocrystal growth. An isocrystalline core/shell preparative method is developed that allows synthesis of internally doped Co²⁺:CdS quantum dots through encapsulation of surface-bound ions beneath additional layers of CdS.