Excitons in InP, GaP, GaInP quantum dots: Insights from time-dependent density functional theory

TL;DR

This study uses advanced density functional theory to analyze the electronic and excitonic properties of InP, GaP, and GaInP quantum dots, revealing size-dependent optical behaviors and structural-electronic correlations.

Contribution

It provides detailed theoretical insights into the size, electronic, and optical properties of group III-V quantum dots, including predictions of excitonic effects and structural-property relationships.

Findings

Optical gap of InP QD scales nearly linearly with inverse diameter.

Radiative exciton decay lifetime increases linearly with dot size.

Vegard's law holds for GaInP alloyed quantum dots at small sizes.

Abstract

Colloidal quantum dots (QDs) of group III-V are considered as promising candidates for next-generation environmentally friendly light emitting devices, yet there appears to be only limited understanding of the underlying electronic and excitonic properties. Using large-scale density functional theory with the hybrid B3LYP functional solving the single-particle states and time-dependent density functional theory accounting for the many-body excitonic effects, we have identified the structural, electronic and excitonic optical properties of InP, GaP and GaInP QDs containing up to a thousand atoms or more. The calculated optical gap of InP QD appears in excellent agreement with available experiments, and it scales nearly linearly with the inverse diameter. The radiative exciton decay lifetime is found to increase surprisingly linearly with increasing the dot size. For GaP QDs, we predict an unusual electronic state crossover at diameter around 1.5 nm whereby the nature of the lowest unoccupied molecular orbital (LUMO) state switches its symmetry from $\Gamma_{5}$-like at larger diameter to $\Gamma_{1}$-like at smaller diameter. After the crossover, the absorption intensity of the band-edge exciton states is significantly enhanced. Finally, we find that Vegard's law holds very well for GaInP random alloyed quantum dots down to ultra-small sizes with less than a hundred atoms. The obtained energy gap bowing parameter of this common-cation compound in QD regime appears positive, size-dependent and much smaller than its bulk parentage. The volume deformation, dominating over the charge exchange and structure relaxation effects, is mainly responsible for the QD energy gap bowing. The present work provides a road map for a variety of electronic and optical properties of colloidal QDs in group III-V that can guide spectroscopic studies.