Valley polarized current and resonant electronic transport in a non-uniform \(\mathbf{MoS}_2\) zigzag nanoribbon

Using the tight-binding approach we study the electronic transport in a \(\mathrm{MoS}_2\) zigzag ribbon with a spatially varying potential profile. Considering a ribbon with a smooth potential step in the Fermi energy regime where the transport is dominated by the edge modes, we find that the condu...

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Bibliographic Details
Published in:arXiv.org 2020-05
Main Authors: Gut, D, Prokop, M, Sticlet, D, Nowak, M P
Format: Article
Language:English
Subjects:
Conduction bands
Electron transport
Hall effect
N-p-n junctions
Nanoribbons
P-n junctions
Resistance
Wire
Online Access:Get full text
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Summary:Using the tight-binding approach we study the electronic transport in a \(\mathrm{MoS}_2\) zigzag ribbon with a spatially varying potential profile. Considering a ribbon with a smooth potential step in the Fermi energy regime where the transport is dominated by the edge modes, we find that the conductance exhibits sharp resonances due to the resonant transport through a n-p-n junction effectively created in the structure. We show that in a gated wire the current carried on the wire edges can be blocked despite the metallic band structure of the ribbon. For the Fermi energies corresponding to \(\mathrm{MoS}_2\) bulk conduction band, we identify states of the semi-infinite wire that are polarized in the \(K\), \(K'\), \(Q\) valleys and exhibit the valley Hall effect distinctly visible in a nonuniform ribbon. Finally, we show that well-defined momenta of the valley polarized modes allow nearly complete valley polarization of the current in a locally gated ribbon.
ISSN:2331-8422
DOI:10.48550/arxiv.1909.13738