Carlos Segarra, Josep Planelles, Juan I. Climente
Published 2017-09-27Version 1
We study the electronic structure of monolayer MoS$_2$ quantum dots subject to a perpendicular magnetic field. The coupling between conduction and valence band gives rise to mid-gap topological states which localize near the dot edge. These edge states are analogous to those of 1D quantum rings. We show they present a large, Zeeman-like, linear splitting with the magnetic field, anticross with the delocalized Fock-Darwin-like states of the dot, give rise to Aharonov-Bohm-like oscillations of the conduction (valence) band low-lying states in the K (K') valley, and modify the strong field Landau levels limit form of the energy spectrum.
Comments: submitted as extension to Chapter 17 of "Physics of Quantum Rings" (Springer, ed.V. Fomin), 2nd edition
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