Bottom-up graphene nanoribbon(GNR) device based on van der Waals heterostructure

ORAL

Abstract

Driven by recent experimental breakthroughs via a bottom-up approach, a new exciting material candidate in the form of just few atoms wide graphene nanoribbons (GNRs) are emerging as strong candidates for realizing molecular electronics. GNRs are predicted to exhibit a rich variety of electronic and magnetic behaviors.
Although substantial efforts have been devoted, the field of bottom-up GNR device exploration is still in its infancy such that the device taking advantages of GNR’s extraordinary properties hasn’t yet been successfully demonstrated. Thus, developing novel nanoscale architectures that make the most out of GNRs’ potential is essential and prerequisite for further investigation. Here, we show a new bottom-up GNR nanostructure-based platform via dry transfer method to harness exciting physical phenomena. Using our device concept, we integrate top-down and bottom-up techniques to demonstrate high quality GNR devices. Bottom-up GNRs are small enough to bring their quantum mechanical nature to GNR devices that could exhibit quantum effect, even at ambient temperature, which has been elusive in conventional electronics. Our work will be an important step towards opening the new possibility of realizing 1-nm scale electronics in the post-silicon era.

Presenters

  • Kyunghoon Lee

    • University of California
    • Physics, UC Berkeley

Authors

  • Kyunghoon Lee

    • University of California
    • Physics, UC Berkeley

  • Shuang Wu

    • University of California
    • EECS, UC Berkeley

  • Gabriela Borin Barin

    • Empa
    • Surfaces laboratory, EMPA

  • Juan Llinas

    • University of California
    • EECS, UC Berkeley

  • Young-Jae Shin

    • Physics, Harvard University
    • Physics, Harvard

  • Philip Kim

    • Physics, Harvard University
    • Harvard University
    • Department of Physics, Harvard University
    • Harvard Univ
    • Physics, Harvard
    • Department of Physics, Harvard university
    • School of Applied Sciences and Engineering, Harvard University

  • Roman Fasel

    • Empa
    • Surfaces laboratory, EMPA

  • Felix Fisher

    • Chemistry, UC Berkeley
    • Chemistry, University of California - Berkeley

  • Michael Crommie

    • Physics, Univ of California - Berkeley
    • UC Berkeley and LBNL
    • Univ of California - Berkeley
    • UCB
    • Physics, UC Berkeley
    • Physics, University of California, Berkeley
    • Department of physics, University of California - Berkeley
    • Physics, University of California - Berkeley

  • Jeffrey Bokor

    • University of California
    • EECS, UC Berkeley
    • Department of Electrical Engineering and Computer Science, University of California, Berkeley
    • EECS, University of California Berkeley

  • Alex Zettl

    • UC Berkeley and LBNL
    • UC berkeley
    • Univ of California - Berkeley
    • Physics, UC Berkeley
    • Physics, University of California, Berkeley
    • University of California at Berkeley
    • Physics, University of California - Berkeley
    • Department of Physics, Univ of California - Berkeley