Abstract
We report exact numerically calculated ground state and binding energies of a hydrogenic donor impurity confined everywhere inside a spherical quantum dot (QD) surrounded by air or a vacuum. Finite spatial steplike potentials allowing the electronic density to partially leak outside the QD are considered. This model faces a divergence produced by the self-polarization potential at the position of the dielectric mismatch. We bypass it by replacing the edge steplike dielectric mismatch by a continuous variation within an extremely thin layer at this edge. A comprehensive study of several confining factors influencing electronic and binding energies is carried out and a highly nonadditive interplay is found. Our calculations show that within both the strong and weak confinement regimes we may be faced with three different behavior regimes. We call them low, intermediate, and high. In the low and intermediate behaviors, the mass, polarization, and self-polarization effects exert a very strong influence on the electron density distribution, so that perturbational estimations of the binding energy may not be appropriate even in the strong confinement regime. These low and intermediate behavior regimes are responsible for binding energy profiles not being monotonously decreasing vs off-centering. It is even theoretically possible to design systems with off-centering independent binding energies.
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