• DocumentCode
    740011
  • Title

    Graphene FETs With Aluminum Bottom-Gate Electrodes and Its Natural Oxide as Dielectrics

  • Author

    Wei Wei ; Xin Zhou ; Deokar, Geetanjali ; Haechon Kim ; Belhaj, Mohamed Moez ; Galopin, Elisabeth ; Pallecchi, Emiliano ; Vignaud, Dominique ; Happy, Henri

  • Author_Institution
    Inst. of Electron., Microelectron. & Nanotechnol., Villeneuve d´Ascq, France
  • Volume
    62
  • Issue
    9
  • fYear
    2015
  • Firstpage
    2769
  • Lastpage
    2773
  • Abstract
    In this paper, we present a fabrication process of graphene field effect transistors (GFETs) using natural oxidation of aluminum as dielectrics, which provide an alternative fabrication choice for future flexible electronics with the large scale and arbitrary substrates. The high-quality monolayer graphene is preserved by our process, and the mobility up to 3250 cm2/Vs is measured after whole device fabrication. GFETs with double bottom-gate structure varying from 300 to 100 nm in gate length have been characterized by both static and dynamic measurements. The total gate capacitances of our device structure are evaluated based on the measurement results of scattering parameters.We report an intrinsic current gain cutoff frequency ( ft-int) of 11 GHz and a maximum oscillation frequency ( fmax) of 8 GHz in devices with 100 nm gate length. Moreover, both the values of ft-int and fmax for different gate lengths are also discussed. Our results indicate that the full process exhibits great potential, especially for graphene-based flexible electronics.
  • Keywords
    S-parameters; aluminium; dielectric materials; electrodes; graphene devices; microwave field effect transistors; monolayers; Al; C; aluminum bottom-gate electrodes; aluminum dielectrics; double bottom-gate structure; dynamic measurements; frequency 11 GHz; frequency 8 GHz; graphene FET; graphene field effect transistors; high-quality monolayer graphene; natural oxide dielectrics; scattering parameters; static measurements; Capacitance; Current measurement; Fabrication; Graphene; Logic gates; Substrates; Transistors; Graphene; natural oxide; radio-frequency(RF) characterization; transfer; transistor; transistor.;
  • fLanguage
    English
  • Journal_Title
    Electron Devices, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9383
  • Type

    jour

  • DOI
    10.1109/TED.2015.2459657
  • Filename
    7185388