• DocumentCode
    3485815
  • Title

    Will strain be useful for 10nm quasi-ballistic FDSOI devices? An experimental study

  • Author

    Barral, V. ; Poiroux, T. ; Rochette, F. ; Vinet, M. ; Barraud, S. ; Faynot, O. ; Tosti, L. ; Andrieu, F. ; Casse, M. ; Previtali, B. ; Ritzenthaler, R. ; Grosgeorges, P. ; Bernard, E. ; LeCarval, G. ; Munteanu, D. ; Autran, J.L. ; Deleonibus, S.

  • Author_Institution
    CEA/LETI MINATEC, Grenoble
  • fYear
    2007
  • fDate
    12-14 June 2007
  • Firstpage
    128
  • Lastpage
    129
  • Abstract
    For the first time, we have extracted the ballisticity rates of strained and unstrained n-fully depleted silicon on insulator devices with gate lengths down to 10 nm. Thanks to a new fully experimental extraction methodology taking into account multi-subband population, we demonstrate that strain takes actively part in quasi-ballistic drain current improvement thanks to a 22% injection velocity enhancement, which will become the predominant transport parameter for the next generation of CMOS devices. In addition, we find that strained channel ballisticity rates are slightly greater than unstrained ones whatever the considered temperature and gate length. This rate improvement can be closely related to the mobility gain for short channel architectures.
  • Keywords
    CMOS integrated circuits; silicon-on-insulator; transistors; CMOS devices; channel ballisticity rates; injection velocity enhancement; n-fully depleted silicon on insulator devices; quasi-ballistic FDSOI devices; quasiballistic drain current; size 10 nm; transistor; Backscatter; Capacitive sensors; Electrostatics; Intrusion detection; MOSFETs; Silicon on insulator technology; Strain control; Temperature; Tensile strain; Transistors;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    VLSI Technology, 2007 IEEE Symposium on
  • Conference_Location
    Kyoto
  • Print_ISBN
    978-4-900784-03-1
  • Type

    conf

  • DOI
    10.1109/VLSIT.2007.4339754
  • Filename
    4339754