A. Matulis
Published 2002-06-11Version 1
The electron motion in rather strong magnetic fields (when only the lowest Landau level is populated) is considered. In this case the electron kinetic energy is frozen out and the electrons are guided by slowly varied potential. Using the adiabatic procedure and expansion in magnetic length series the approximate description is developed. In zero order this approximation leads to the classical equations of motion describing the Larmor circle drift in the potential gradient. In the second order the special quantum mechanical description where the electron potential energy plays the role of the total Hamiltonian is constructed. Simple examples of a single and two electrons in the parabolic dot demonstrates that the proposed approximate description gives the main features of the electron system spectrum and the collective phenomena.
Comments: 10 pages, 5 figures, RevTeX4
Journal: In book "Nano-Physics & Bio-Electronics: A New Odyssey", ed. by T. Chakraborty, F. Peeters and U. Sivan, ELSEVIER, 2002, p. 237-255
Coulomb effects on the transport properties of quantum dots in strong magnetic field
Effect of matrix parameters on mesoporous matrix based quantum computation
Resonant tunneling and Fano resonance in quantum dots with electron-phonon interaction
