Coulomb drag between carbon nanotube and graphene

Jean-Damien Pillet, Austin Cheng, Takashi Taniguchi, Kenji Watanabe, Philip Kim

Published 2016-12-18Version 1

When two electrically isolated conductors are brought close, a current in one conductor can generate friction and drag electrons in the other via Coulomb interaction, thereby causing a charge imbalance in the dragged layer. This is known as Coulomb drag and has been used to investigate strongly correlated nature of low dimensional conductors. Here, we report the observation of Coulomb drag between a two-dimensional electron gas in graphene and a one-dimensional wire composed of a carbon nanotube. We find that drag occurs when the bulk of graphene is conducting, but is strongly suppressed in the quantum Hall regime when magnetic field confines conducting electrons to the edges of graphene and far from the nanotube. Out-of-equilibrium measurements show that transitions between quantized charge states of the nanotube induce either strong suppression or enhancement of drag signal.