Abstract
We investigate in this work the quantum confinement effect of exciton in spherical inhomogeneous quantum dots IQDs. The spherical core is enveloped by two shells. The inner shell is a semiconductor characterized by a small band-gap. The core and the outer shell are the same semiconductor characterized by a large band-gap. So there is a significant gap-offset creating a deep potential well where the excitons are localized and strongly confined. We have adopted the Ritz variational method to calculate numerically the excitonic ground state energy and its binding energy in the strong, moderate and low confinement regimes. The results show that the Ritz variational method is in good agreement with the perturbation method in strong confinement. There is a double confinement effect and dual control. The calculation checks the effective Rydberg R* at the asymptotic limit of bulk semiconductor when the thickness takes very large values. The excitonic binding energy increases, Thus giving the excitons a high stability even at ambient temperature. These nanosystems are promising in several applications: lighting, detection, biological labeling and quantum computing.
Highlights
The inhomogeneous quantum dots IQDs Core/shell/shell were developed to improve the photoluminescence quantum efficiency QE of single QDs
In a previous paper[6] we have studied the excitonic transitions in our inhomogeneous QDs core/well/shell with the perturbation method in strong confinement
HgS the values of excitonic binding energy of ground state calculated by perturbation and variational methods and gives the uncertainties observed δEb = EbV − EbP
Summary
The inhomogeneous quantum dots IQDs Core/shell/shell were developed to improve the photoluminescence quantum efficiency QE of single QDs. In a previous paper[6] we have studied the excitonic transitions in our inhomogeneous QDs core/well/shell with the perturbation method in strong confinement.
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