Electromagnetic field induced suppression of transport through n-p junctions in graphene
Abstract
We study quasi-particle transmission through an n -p junction in a graphene irradiated by an electromagnetic field (EF). In the absence of EF the electronic spectrum of undoped graphene is gapless, and one may expect the perfect transmission of quasi-particles flowing perpendicular to the junction. We demonstrate that the resonant interaction of propagating quasi-particles with the component of EF parallel to the junction induces a non-equilibrium dynamic gap (2R) between electron and hole bands in the quasi-particle spectrum of graphene. In this case the strongly suppressed quasi-particle transmission is only possible due to interband tunnelling. The effect may be used for controlling transport properties of diverse structures in graphene, like, e.g., n-p-n transistors, single electron transistors, quantum dots, etc., by variation of the intensity S and frequency ω of the external radiation.
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