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Abstract
The electronic structure and binding energy of a hydrogenic acceptor impurity in 2, 1, and 0-dimensional semiconductor nano-structures (i.e. quantum well (QW), quantum well wire (QWW), and quantum dot (QD)) are studied in the framework of effective-mass envelope-function theory. The results show that (1) the energy levels monotonically decrease as the quantum confinement sizes increase; (2) the impurity energy levels decrease more slowly for QWWs and QDs as their sizes increase than for QWs; (3) the changes of the acceptor binding energies are very complex as the quantum confinement size increases; (4) the binding energies monotonically decrease as the acceptor moves away from the nano-structures’ center; (5) as the symmetry decreases, the degeneracy is lifted, and the first binding energy level in the QD splits into two branches. Our calculated results are useful for the application of semiconductor nano-structures in electronic and photoelectric devices.
Highlights
Impurity states play a very important role in the semiconductor revolution
Galiev and Polupanov calculated the energy levels and oscillator strengths from the ground state to the odd excited states of an acceptor located at the center of a spherical quantum dot (QD) in the effective mass approximation [8]
For a hydrogenic acceptor impurity located at r0 1⁄4 ðx0; y0; z0Þ in a semiconductor nano-structure, the electron envelope function equation in the framework of the effective-mass approximation is wnðrÞ 1⁄4 EnawnðrÞ; ð1Þ
Summary
Impurity states play a very important role in the semiconductor revolution. Hydrogenic impurities, including donorsS.-S. Buonocore et al presented results on the ground-state binding energies for donor and acceptor impurities in a deformed quantum well wire (QWW) [6].
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