مرکز منطقه ای اطلاع رساني علوم و فناوري - Electron energy state spin-splitting in nanoscale InAs/GaAs semiconductor quantum dots and rings

DocumentCode :

2060857

Title :

Electron energy state spin-splitting in nanoscale InAs/GaAs semiconductor quantum dots and rings

Author :

Li, Yiming ; Lu, Hsiao-Mei

Author_Institution :

Dept. of Nano Device Technol., Nat. Nano Device Lab., Hsinchu, Taiwan

Volume :

fYear :

2003

fDate :

12-14 Aug. 2003

Firstpage :

885

Abstract :

We study the effect of spin-orbit interaction for different shape semiconductor quantum nanostructures. The effective one-band Hamiltonian approximation, the position- and energy-dependent quasi-particle effective mass approximation, the finite hard wall confinement potential, and the spin-dependent Ben Daniel-Duke boundary conditions are considered and solved numerically in this work. The spin-orbit interaction which comes from the spin-dependent boundary conditions is characterized for InAs/GaAs quantum dots and quantum rings. We find it can significantly modify the electron energy spectrum for InAs semiconductor quantum dots and quantum rings built in the GaAs matrix. The energy state spin-splitting strongly depends on the geometry of nanostructures. It has an experimentally measurable magnitude for ultra-small quantum dots and quantum rings with non-zero angular momentum.

Keywords :

III-V semiconductors; conduction bands; electron spectra; energy gap; gallium arsenide; indium compounds; nanostructured materials; semiconductor quantum dots; spin-orbit interactions; GaAs matrix; InAs-GaAs; electron energy spectra; electron energy state spin splitting; energy dependent quasi particle effective mass approximation; finite hard wall confinement potential; nanoscale InAs/GaAs semiconductor quantum dots; nanoscale InAs/GaAs semiconductor quantum rings; nanostructures; nonzero angular momentum; one band Hamiltonian approximation; position dependent quasi particle effective mass approximation; spin dependent Ben Daniel Duke boundary conditions; spin orbit interaction; Atom optics; Boundary conditions; Effective mass; Electrons; Energy states; Gallium arsenide; Geometry; Quantum dots; Semiconductor nanostructures; US Department of Transportation;

fLanguage :

English

Publisher :

ieee

Conference_Titel :

Nanotechnology, 2003. IEEE-NANO 2003. 2003 Third IEEE Conference on

Print_ISBN :

0-7803-7976-4

Type :

conf

DOI :

10.1109/NANO.2003.1231057

Filename :

1231057

Link To Document :

https://search.ricest.ac.ir/dl/search/defaultta.aspx?DTC=49&DC=2060857