Time-dependent transport in graphene nanoribbons

Abstract

We theoretically investigate the time-dependent ballistic transport in metallic graphene nanoribbons after the sudden switch-on of a bias voltage V. The ribbon is divided in three different regions, namely two semi-infinite graphenic leads and a central part of length L, across which the bias drops linearly and where the current is calculated. We show that during the early transient time the system behaves like a graphene bulk under the influence of a uniform electric field E=V/L. In the undoped system the current does not grow linearly in time but remarkably reaches a temporary plateau with dc conductivity σ1=π e2/2h, which coincides with the minimal conductivity of two-dimensional graphene. After a time of order L/vF (vF being the Fermi velocity) the current departs from the first plateau and saturates at its final steady state value with conductivity σ2=2e2/h typical of metallic nanoribbons of finite width.