W. J. Schaff scite author profile

The electronic structure of clean InN(0001) surfaces has been investigated by high-resolution electron-energy-loss spectroscopy of the conduction band electron plasmon excitations. An intrinsic surface electron accumulation layer is found to exist and is explained in terms of a particularly low Gamma-point conduction band minimum in wurtzite InN. As a result, surface Fermi level pinning high in the conduction band in the vicinity of the Gamma point, but near the average midgap energy, produces charged donor-type surface states with associated downward band bending. Semiclassical dielectric theory simulations of the energy-loss spectra and charge-profile calculations indicate a surface state density of 2.5 (+/-0.2)x10(13) cm(-2) and a surface Fermi level of 1.64+/-0.10 eV above the valence band maximum.

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Origin of electron accumulation at wurtzite InN surfaces

Mahboob

et al. 2004

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Energy position of near-band-edge emission spectra of InN epitaxial layers with different doping levels

et al. 2004

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Evidence forp-Type Doping of InN

et al. 2006

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The first evidence of successful p-type doping of InN is presented. It is shown that InN:Mg films consist of a p-type bulk region with a thin n-type inversion layer at the surface that prevents electrical contact to the bulk. Capacitance-voltage measurements indicate a net concentration of ionized acceptors below the -type surface. Irradiation with 2 MeV He+ ions is used to convert the bulk of InN:Mg from p to n-type, at which point photoluminescence is recovered. The conversion is well explained by a model assuming two parallel conducting layers (the surface and the bulk) in the films.

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Growth of cubic InN on r-plane sapphire

Cimalla

Pezoldt

Ecke

et al. 2003

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W. J. Schaff

Intrinsic Electron Accumulation at Clean InN Surfaces

Origin of electron accumulation at wurtzite InN surfaces

Energy position of near-band-edge emission spectra of InN epitaxial layers with different doping levels

Evidence forp-Type Doping of InN

Growth of cubic InN on r-plane sapphire

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