Collimated Ballistic Quasiparticle Transport in a Graphene/hBN Superlattice

ORAL

Abstract

Moiré patterns in van der Waals heterostructures of graphene and other hexagonal crystals such as boron nitride (hBN) are a readily realizable class of 2D superlattices with electronic properties distinct from those of the parent materials. Transport measurements of highly aligned graphene/hBN superlattices showed a band structure with miniband edges, van Hove singularities, and non-circular cyclotron orbits [M. Lee et al, Science 353, 6307 (2016)]. However, several interesting regimes are obscured by the coexistence of multiple bands in different parts of k-space.
We have recently developed a way to inject collimated beams of electrons into a sheet of graphene: absorptive pinhole collimators, consisting of absorptive sidewalls between a pair of collinear slits, emit beams with angular spread 18 degrees full width at half maximum [A. Barnard et al, Nat. Comm. 8, 15418 (2017)]. This means the collimators populate and/or detect a narrow window of k-states. By filtering orbits in k-space, we can study orbits within specific bands. Here we use collimated beams generated by pinhole collimators in highly aligned graphene/hBN heterostructures to finely probe superlattice band structure and explore possible valley filtering.

Presenters

  • Aaron Sharpe

    • Stanford Univ
    • Stanford University

Authors

  • Aaron Sharpe

    • Stanford Univ
    • Stanford University

  • Arthur Barnard

    • Stanford Univ
    • Stanford University

  • John Wallbank

    • National Graphene Institute, University of Manchester

  • Kenji Watanabe

    • National Institute for Materials Science
    • NIMS
    • National Institute for Material Science
    • Advanced Materials Laboratory, National Institute for Materials Science
    • National Institute of Materials Science
    • Research Center for Functional Materials, National Institute for Materials Science
    • National Institute for Materials Science (NIMS
    • Advanced Materials Laboratory, NIMS
    • National Institute for Materials Science, Advanced Materials Laboratory
    • National Institue for Materials Science
    • National Institute of Material Science
    • National Institute for Matericals Science
    • Advanced Materials Laboratory
    • National Institute for Materials Science, 1-1 Namiki
    • Advanced materials laboratory, National institute for Materials Science
    • NIMS-Japan

  • Takashi Taniguchi

    • National Institute for Materials Science
    • NIMS
    • National Institute for Material Science
    • Advanced Materials Laboratory, National Institute for Materials Science
    • National Institute of Materials Science
    • Research Center for Functional Materials, National Institute for Materials Science
    • National Institute for Materials Science (NIMS
    • Advanced Materials Laboratory, NIMS
    • National Institute for Materials Science, Advanced Materials Laboratory
    • National Institue for Materials Science
    • National Institute of Material Science
    • National Institute for Matericals Science
    • Advanced Materials Laboratory
    • National Institute for Materials Science, 1-1 Namiki
    • NIMS-Japan

  • David Goldhaber-Gordon

    • Department of Physics, Stanford University
    • Stanford University
    • Physics, Stanford University
    • Stanford Univ