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Tunable transmission via quantum state evolution in oval quantum dots

We explore the quantum transmission through open oval shaped quantum dots. The transmission spectra show periodic resonances and, depending on the geometry parameter, a strong suppression of the transmission for low energies. Applying a weak perpendicular magnetic field changes this situation drasti...

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Published in:	arXiv.org 2007-12
Main Authors:	Buchholz, D, Drouvelis, P, Schmelcher, P
Format:	Article
Language:	English
Subjects:	Decoupling Magnetic fields Magnetic properties Quantum dots Quantum theory Resistance
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creator	Buchholz, D Drouvelis, P Schmelcher, P
description	We explore the quantum transmission through open oval shaped quantum dots. The transmission spectra show periodic resonances and, depending on the geometry parameter, a strong suppression of the transmission for low energies. Applying a weak perpendicular magnetic field changes this situation drastically and introduces a large conductance. We identify the underlying mechanisms being partially due to the specific shape of the oval that causes a systematic decoupling of a substantial number of states from the leads. Importantly a pairwise destructive interference of the transmitting states is encountered thereby leading to the complete conductance suppression. Coupling properties and interferences can be tuned via a weak magnetic field. These properties are robust with respect to the presence of disorder in the quantum dot.
doi_str_mv	10.48550/arxiv.0712.0682
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subjects	Decoupling Magnetic fields Magnetic properties Quantum dots Quantum theory Resistance
title	Tunable transmission via quantum state evolution in oval quantum dots
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