• DocumentCode
    1761270
  • Title

    TFET-Based Circuit Design Using the Transconductance Generation Efficiency  {g}_{m}/ {I}_{d} Method

  • Author

    Barboni, Leonardo ; Siniscalchi, Mariana ; Sensale-Rodriguez, Berardi

  • Author_Institution
    Dept. of Electr. Eng., Univ. de la Republica, Montevideo, Uruguay
  • Volume
    3
  • Issue
    3
  • fYear
    2015
  • fDate
    42125
  • Firstpage
    208
  • Lastpage
    216
  • Abstract
    Tunnel field effect transistors (TFETs) have emerged as one of the most promising post-CMOS transistor technologies. In this paper, we: 1) review the perspectives of such devices for low-power high-frequency analog integrated circuit applications (e.g., GHz operation with sub-0.1 mW power consumption); 2) discuss and employ a compact TFET device model in the context of the gm/Id integrated analog circuit design methodology; and 3) compare several proposed TFET technologies for such applications. The advantages of TFETs arise since these devices can operate in the sub-threshold region with larger transconductance-to-current ratio than traditional FETs, which is due to the current turn-on mechanism being interband tunneling rather than thermionic emission. Starting from technology computer-aided design and/or analytical models for Si-FinFETs, graphene nano-ribbon (GNR) TFETs and InAs/GaSb TFETs at the 15-nm gate-length node, as well as InAs double-gate TFETs at the 20-nm gate-length node, we conclude that GNR TFETs might promise larger bandwidths at low-voltage drives due to their high current densities in the sub-threshold region. Based on this analysis and on theoretically predicted properties, GNR TFETs are identified as one of the most attractive field effect transistor technologies proposed-to-date for ultra-low power analog applications.
  • Keywords
    CAD; III-V semiconductors; MOSFET; analogue integrated circuits; elemental semiconductors; gallium compounds; graphene devices; indium compounds; nanoribbons; semiconductor device models; silicon; C; InAs double-gate TFET; InAs-GaSb; InAs/GaSb TFET; Si; Si-FinFET; TFET-based circuit design; compact TFET device model; computer-aided design; current turn-on mechanism; gm/Id integrated analog circuit design methodology; graphene nanoribbon TFET; interband tunneling; low-power high-frequency analog integrated circuit applications; size 15 nm to 20 nm; sub-threshold region; transconductance generation efficiency; transconductance-to-current ratio; tunnel field effect transistors; Analytical models; Circuit synthesis; Field effect transistors; Integrated circuit modeling; Logic gates; Mathematical model; $g_{m}/I_{d}$ method; Si-FinFETs; Tunnel-FET; gm/Id method; one-stage common-source amplifier; tunnel field effect transistors (TFET); two-stage OTA with Miller effect compensation; two-stage operational transconductance amplifier (OTA) with Miller effect compensation; ultra low power design; ultra-low power design;
  • fLanguage
    English
  • Journal_Title
    Electron Devices Society, IEEE Journal of the
  • Publisher
    ieee
  • ISSN
    2168-6734
  • Type

    jour

  • DOI
    10.1109/JEDS.2015.2412118
  • Filename
    7058334