Asymmetric Stark shift in an impurity doped dome-shaped quantum dot with wetting layer

[Display omitted] •Electron states for a dome-shaped InAs/GaAs QD under electric field are calculated.•The Stark shift of the donor energy has a quadratic dependence on the applied field.•The WL-state energy reveal a peculiar behavior for small and large electric fields.•The donor polarizability dep...

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Bibliographic Details
Published in:Chemical physics 2017-02, Vol.483-484, p.132-139
Main Authors: Niculescu, E.C., Cristea, M., Bejan, D.
Format: Article
Language:English
Subjects:
Dipole moment
Donor impurity
Electric field
Polarizability
Quantum dot
Stark shift
Wetting layer
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Summary:[Display omitted] •Electron states for a dome-shaped InAs/GaAs QD under electric field are calculated.•The Stark shift of the donor energy has a quadratic dependence on the applied field.•The WL-state energy reveal a peculiar behavior for small and large electric fields.•The donor polarizability depends substantially on the impurity position. The effects of vertical electric field and donor impurity on the electronic properties of the dome-shaped InAs/GaAs quantum dot coupled to its wetting layer were investigated. The dependence of the electron density, energy and Stark shift of the S-, P- and WL-states on the applied electric field was studied with and without impurity. The S- and P-states have no significant qualitative changes in the shape of the wave functions with increasing the electric field, except that they become slightly shifted due to the competition between the field action and the quantum confinement. The wave function of the WL-state is strongly modified in polarized structures. Our results reveal that the Stark shift of electron energies can be fitted with a quadratic dependence on the electric field, the linear and quadratic terms corresponding to the dipole moment and static electron polarizability. Their estimated values reasonable agree with those calculated.
ISSN:0301-0104
DOI:10.1016/j.chemphys.2016.12.005