Collective Edge Excitations In The Quantum Hall Regime: Edge Helicons And Landau-level Structure
O. G. Balev (1), P. Vasilopoulos (2) ((1) Institute of Physics of, Semiconductors Kiev, Ukraine, (2) Concordia University, Department of, Physics, Montreal, Canada)
TL;DR
This paper develops a microscopic theory of edge magnetoplasmons in quantum Hall systems, identifying nearly undamped edge helicon modes and analyzing Landau level interactions, with results aligning with recent experimental observations.
Contribution
It introduces a detailed microscopic model for edge magnetoplasmons that accounts for Landau level structure and electron-phonon interactions, highlighting the existence of edge helicons.
Findings
Existence of nearly undamped edge helicon modes.
Strong inter-Landau level Coulomb coupling effects.
Good agreement with experimental data.
Abstract
Based on a microscopic evaluation of the local current density, a treatment of edge magnetoplasmons (EMP) is presented for confining potentials that allow Landau level (LL) flattening to be neglected. Mode damping due to electron-phonon interaction is evaluated. For nu=1, 2 there exist independent modes spatially symmetric or antisymmetric with respect to the edge. Certain modes, changing shape during propagation, are nearly undamped even for very strong dissipation and are termed edge helicons. For nu > 2 inter-LL Coulomb coupling leads to a strong repulsion of the decoupled LL fundamental modes. The theory agrees well with recent experiments.
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