Related papers: Tunneling Effect in Gapped Graphene Disk in Magnetic Flux and Electrostatic Potential

Tunneling Effect in Gapped Graphene Disk in Magnetic Flux and Electrostatic Potential

URL: http://arxiv.org/abs/2108.01159v1
Date: Mon, 2 Aug 2021 20:38:27 GMT
Title: Tunneling Effect in Gapped Graphene Disk in Magnetic Flux and Electrostatic Potential
Authors: A. Babe Cheikh, A. Bouhlal, A. Jellal, E. H. Atmani
Abstract summary: We investigate the tunneling effect of a Corbino disk in graphene in the presence of a variable magnetic flux $Phi_i$ created by a solenoid piercing the inner disk. Considering different regions, we explicitly determine the associated eigenspinors in terms of Hankel functions.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We investigate the tunneling effect of a Corbino disk in graphene in the presence of a variable magnetic flux $\Phi_{i}$ created by a solenoid piercing the inner disk under the effect of a finite mass term in the disk region $ (R_1< r<R_2) $ and an electrostatic potential. Considering different regions, we explicitly determine the associated eigenspinors in terms of Hankel functions. The use of matching conditions and asymptotic behavior of Hankel functions for large arguments, enables us to calculate transmission and other transport quantities. Our results show that the energy gap suppresses the tunneling effect by creating singularity points of zero transmission corresponding to the maximum shot noise peaks quantified by the Fano factor $ F $. The transmission as a function of the radii ratio $ R_2/R_1 $ becomes oscillatory with a decrease in periods and amplitudes. It can even reach one (Klein tunneling) for large values of the energy gap. The appearance of the minimal conductance at the points $ k_F R_1=R_1 \delta$ is observed. Finally we find that the electrostatic potential can control the effect of the band gap.

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