• DocumentCode
    1213704
  • Title

    Inp/langmuir-film m.i.s.f.e.t.

  • Author

    Roberts, G.G. ; Pande, K.P. ; Barlow, W.A.

  • Author_Institution
    University of Durham, Department of Applied Physics and Electronics, Science Laboratories, Durham, UK
  • Volume
    2
  • Issue
    6
  • fYear
    1978
  • fDate
    11/1/1978 12:00:00 AM
  • Firstpage
    169
  • Lastpage
    175
  • Abstract
    The electrical properties of m.i.s. structures based on indium phosphide and organic films deposited using the Langmuir-Blodgett technique have been investigated. A strongly inverted low-frequency C/V response occurs at approximately 30 Hz using both melt-grown InP single crystals and epitaxial layers of this material prepared using the vapour-phase technique. Interface state distributions have been evaluated from the admittance data using quasistatic and conductance techniques. For an n-type InP-epitaxial-wafer/cadmium-stearate junction the effective surface-state density is found to be ~3 ¿¿ 1011 cm¿¿2 eV¿¿1 over a large fraction of the bandgap. Average surface-state densities calculated for structures based on melt-grown crystals were approximately one order of magnitude higher. For the first time measurements are reported for a transistor incorporating a Langmuir-Blodgett film. From the transfer characteristics of this relatively simple depletion-mode device the InP field-effect surface mobility is calculated to be 2250 cm2 V¿¿1 s¿¿1
  • Keywords
    Langmuir films; insulated gate field effect transistors; interface electron states; InP Langmuir film; Langmuir Blodgett technique; MISFET; depletion mode device; electrical properties; epitaxial layers; field effect transistor; interface state distributions, C-V response; melt grown crystals; organic films; surface mobility; surface state density; transistor;
  • fLanguage
    English
  • Journal_Title
    Solid-State and Electron Devices, IEE Journal on
  • Publisher
    iet
  • ISSN
    0308-6968
  • Type

    jour

  • DOI
    10.1049/ij-ssed.1978.0053
  • Filename
    4807605