Common-path interference and oscillatory Zener tunneling in bilayer graphene p-n junctions

  • Rahul Nandkishore
    Department of Physics, Massachusetts Institute of Technology, Cambridge, MA 02139
  • Leonid Levitov
    Department of Physics, Massachusetts Institute of Technology, Cambridge, MA 02139

書誌事項

公開日
2011-08-08
DOI
  • 10.1073/pnas.1101352108
公開者
Proceedings of the National Academy of Sciences

この論文をさがす

説明

<jats:p> Interference and tunneling are two signature quantum effects that are often perceived as the yin and yang of quantum mechanics: a particle simultaneously propagating along several distinct classical paths versus a particle penetrating through a classically inaccessible region via a single least-action path. Here we demonstrate that the Dirac quasiparticles in graphene provide a dramatic departure from this paradigm. We show that Zener tunneling in gapped bilayer graphene, which governs transport through p-n heterojunctions, exhibits common-path interference that takes place under the tunnel barrier. Due to a symmetry peculiar to the gapped bilayer graphene bandstructure, interfering tunneling paths form conjugate pairs, giving rise to high-contrast oscillations in transmission as a function of the gate-tunable bandgap and other control parameters of the junction. The common-path interference is solely due to forward-propagating waves; in contrast to Fabry–Pérot-type interference in resonant-tunneling structures, it does not rely on multiple backscattering. The oscillations manifest themselves in the junction I–V characteristic as N-shaped branches with negative differential conductivity. The negative <jats:italic>dI</jats:italic> / <jats:italic>dV</jats:italic> , which arises solely due to under-barrier interference, can enable new high-speed active-circuit devices with architectures that are not available in electronic semiconductor devices. </jats:p>

収録刊行物

被引用文献 (2)*注記

もっと見る

詳細情報 詳細情報について

問題の指摘

ページトップへ