• DocumentCode
    1501127
  • Title

    Impact ionization suppression by quantum confinement: Effects on the DC and microwave performance of narrow-gap channel InAs/AlSb HFET´s

  • Author

    Bolognesi, C.R. ; Dvorak, Martin W. ; Chow, David H.

  • Author_Institution
    Sch. of Eng. Sci., Simon Fraser Univ., Burnaby, BC, Canada
  • Volume
    46
  • Issue
    5
  • fYear
    1999
  • fDate
    5/1/1999 12:00:00 AM
  • Firstpage
    826
  • Lastpage
    832
  • Abstract
    InAs/AlSb heterostructure field-effect transistors (HFET´s) are subject to impact ionization induced short-channel effects because of the narrow InAs channel energy gap. In principle, the effective energy gap to overcome for impact ionization can be increased by quantum confinement (channel quantization) to alleviate impact ionization related nonidealities such as the kink effect and a high gate leakage current. We have studied the effects of quantum well thickness on the dc and microwave performance of narrow-gap InAs/AlSb HFET´s fabricated on nominally identical epitaxial layers which differ only by their quantum well thickness. We show that a thinner quantum well postpones the onset of impact ionization and suppresses short-channel effects. As expected, the output conductance gDS and the gate leakage current are reduced. The fMAX/fT ratio is also significantly improved when the InAs well thickness is reduced from 100 to 50 Å. The use of the thinner well reduces the cutoff frequency fT, the transconductance gm, and the current drive because of the reduced low-field mobility due to interface roughness scattering in thin InAs/AlSb channel layers: the low-field mobility was μ=21 000 and 9000 cm2/Vs for the 100- and 50-Å quantum wells, respectively. To our knowledge, the present work is the first study of the link between channel quantization, in-plane impact ionization, and device performance in narrow-gap channel HFET´s
  • Keywords
    III-V semiconductors; aluminium compounds; energy gap; impact ionisation; indium compounds; junction gate field effect transistors; microwave field effect transistors; semiconductor quantum wells; DC characteristics; InAs-AlSb; bandgap engineering; current drive; cutoff frequency; epitaxial layer; gate leakage current; heterostructure field effect transistor; impact ionization; interface roughness scattering; kink effect; low-field mobility; microwave characteristics; narrow-gap channel InAs/AlSb HFET; output conductance; quantization; quantum confinement; quantum well; short-channel effect; transconductance; Cutoff frequency; Epitaxial layers; HEMTs; Impact ionization; Leakage current; MODFETs; Particle scattering; Potential well; Quantization; Transconductance;
  • fLanguage
    English
  • Journal_Title
    Electron Devices, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9383
  • Type

    jour

  • DOI
    10.1109/16.760386
  • Filename
    760386