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Optically modulated tunneling current of dressed electrons in graphene and a dice lattice

Andrii Iurov, Liubov Zhemchuzhna, Godfrey Gumbs, Danhong Huang, Paula Fekete

2022Physical review. B./Physical review. B29 citationsDOI

Abstract

Based on the transmission coefficient of tunneling electrons, we have presented tunneling current and conductivity across a square-potential barrier for both graphene and $\ensuremath{\alpha}\text{\ensuremath{-}}{\mathcal{T}}_{3}$ lattices under a linearly polarized off-resonant dressing field. The presence of such a dressing field introduces an anisotropy factor in the energy dispersion of tunneling electrons so that the cross section of a Dirac cone appears as elliptical. Consequently, the field-polarization controlled major axis of the ellipse will be misaligned with the normal direction of a barrier layer in the tunneling system, which exhibits an asymmetric Klein paradox for an off-normal-direction tunneling. The resulting tunneling current in this system is calculated by using a transmission coefficient and a longitudinal group velocity (different from a longitudinal momentum) of electrons. By presenting numerically calculated tunneling conductivity modified by a laser dressing field, we demonstrate a significant enhancement of electrical conductivity by external laser-field intensity, which is expected to be crucial in the application of ultrafast optical modulation of optoelectronic devices for photodetection and fiber-optic communication.

Topics & Concepts

Quantum tunnellingCondensed matter physicsPhysicsElectronTransmission coefficientGrapheneQuantum mechanicsTransmission (telecommunications)Electrical engineeringEngineeringQuantum and electron transport phenomenaGraphene research and applicationsTopological Materials and Phenomena
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