Current splitting and valley polarization in elastically deformed graphene

TL;DR

This paper explores how elastic deformations in graphene nanoribbons can split electric currents into valley-polarized beams, proposing a valleytronic device that is both efficient and sensitive to deformations.

Contribution

It introduces a novel valleytronic nanodevice utilizing elastic deformations to achieve high electron polarization and transmission, supported by both tight-binding and continuum models.

Findings

Deformations can split current into valley-polarized beams.

The device achieves high polarization with high transmission.

The continuum model provides insight into electron flow behavior.

Abstract

Elastic deformations of graphene can significantly change the flow paths and valley polarization of the electric currents. We investigate these phenomena in graphene nanoribbons with localized out-of-plane deformations by means of tight-binding transport calculations. Such deformations can split the current into two beams of almost completely valley polarized electrons and give rise to a valley voltage. These properties are observed for a fairly wide set of experimentally accessible parameters. We propose a valleytronic nanodevice in which a high polarization of the electrons comes along with a high transmission making the device very efficient. In order to gain a better understanding of these effects, we also treat the system in the continuum limit in which the electronic excitations can be described by the Dirac equation coupled to curvature and a pseudo-magnetic field. Semiclassical trajectories offer then an additional insight into the balance of forces acting on the electrons and provide a convenient tool for predicting the behavior of the current flow paths. The proposed device can also be used for a sensitive measurement of graphene deformations.