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Quantum Confined Systems

Dr. Delerue, Christophe / Dr. Lannoo, Michel

Abstract The electronic structure of bulk semiconductors is characterized by delocalized electronic states and by a quasi continuous spectrum of energies in the conduction and valence bands. In semiconductor nanostructures, when the electrons are confined in small regions of space in the range of a few tens of nanometers or below, the energy spectrum is profoundly affected by the confinement, with in particular: an increase of the width of the bandgap the allowed energies become discrete in zero-dimensional (OD) systems and form mini-bands in 1D and 2D systems.

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Quantum Confined Systems

Dr. Delerue, Christophe / Dr. Lannoo, Michel

Abstract The electronic structure of bulk semiconductors is characterized by delocalized electronic states and by a quasi continuous spectrum of energies in the conduction and valence bands. In semiconductor nanostructures, when the electrons are confined in small regions of space in the range of a few tens of nanometers or below, the energy spectrum is profoundly affected by the confinement, with in particular: an increase of the width of the bandgap the allowed energies become discrete in zero-dimensional (OD) systems and form mini-bands in 1D and 2D systems.

Quantum Confined Systems

Dr. Delerue, Christophe / Dr. Lannoo, Michel

Abstract The electronic structure of bulk semiconductors is characterized by delocalized electronic states and by a quasi continuous spectrum of energies in the conduction and valence bands. In semiconductor nanostructures, when the electrons are confined in small regions of space in the range of a few tens of nanometers or below, the energy spectrum is profoundly affected by the confinement, with in particular: an increase of the width of the bandgap the allowed energies become discrete in zero-dimensional (OD) systems and form mini-bands in 1D and 2D systems.

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Title:

Quantum Confined Systems

Contributors:

Dr. Delerue, Christophe (author) / Dr. Lannoo, Michel (author)

Published in:

Nanostructures ; 47-76

NanoScience and Technology

Publication date:

2004-01-01

Size:

30 pages

ISBN:

978-3-642-05847-9 , 978-3-662-08903-3

ISSN:

DOI:

https://doi.org/10.1007/978-3-662-08903-3_2

Type of media:

Article/Chapter (Book)

Type of material:

Electronic Resource

Language:

English

Keywords:

Tight Binding , Envelope Function , Conduction Band Minimum , Confinement Energy , Tight Binding Calculation Engineering , Nanotechnology and Microengineering , Nanotechnology , Numerical and Computational Physics , Quantum Optics

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