• DocumentCode
    1777218
  • Title

    Graphene nanoribbon plasmonic waveguides: Fundamental limits and device implications

  • Author

    Rakheja, Shaloo ; Sengupta, P.

  • Author_Institution
    Microsyst. Technol. Labs., Massachusetts Inst. of Technol., Cambridge, MA, USA
  • fYear
    2014
  • fDate
    22-25 June 2014
  • Firstpage
    105
  • Lastpage
    106
  • Abstract
    The 2D carbon material graphene exhibits strong light-matter interaction over a very wide wavelength range from the far infrared to the ultraviolet [1]. The tunability of the density-of-states and Fermi energy in graphene along with its excellent transport properties provide a path for graphene photonic applications such as quantum optics, photo-voltaics, photo-detectors, and biological sensing [2]. In this paper, we propose exploiting collective electron-light oscillations or plasmons in patterned graphene nano-ribbons (GNRs) for low energy, high-speed on-chip interconnects that can potentially overcome the latency and power constraints of the current copper/low-K on-chip interconnects [3-4]. The contributions of this paper are threefold. First, compact models for evaluating the plasmon-damping rate in GNRs are introduced. The models account for plasmon-damping pathways through phonons (intrinsic and substrate), substrate charged impurities, and edge-states in ribbons. The compact models introduced in this paper are also applicable to other photonic applications of graphene beyond just on-chip interconnects. Secondly, compact models for evaluating the propagation speed and energy consumption of plasmonic waveguides based on their shot-noise limits are introduced. Finally, the fundamental limits and device implications of on-chip plasmonic waveguides are quantified. In particular, propagation speed and energy consumption are compared with copper/low-K on-chip interconnects at advanced technology nodes.
  • Keywords
    graphene; integrated circuit interconnections; low-k dielectric thin films; nanoribbons; optical waveguides; plasmonics; shot noise; 2D carbon material graphene; Fermi energy; GNRs; advanced technology nodes; biological sensing; collective electron-light oscillations; copper-low-k on-chip interconnects; density-of-states; edge-states; energy consumption; graphene nanoribbon plasmonic waveguides; graphene photonic applications; light-matter interaction; low energy high-speed on-chip interconnects; on-chip plasmonic waveguides; patterned graphene nanoribbons; photodetectors; photovoltaics; plasmon-damping pathways; plasmon-damping rate evaluation; power constraints; propagation speed; quantum optics; shot-noise limits; substrate charged impurities; transport properties; Energy consumption; Graphene; Integrated circuit interconnections; Optical waveguides; Phonons; Plasmons; System-on-chip;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Device Research Conference (DRC), 2014 72nd Annual
  • Conference_Location
    Santa Barbara, CA
  • Print_ISBN
    978-1-4799-5405-6
  • Type

    conf

  • DOI
    10.1109/DRC.2014.6872319
  • Filename
    6872319