Interface states at SiO2/6H-SiC(0001) interfaces observed by x-ray photoelectron spectroscopy measurements under bias:: Comparison between dry and wet oxidation -: art. no. 115305

Interface states in almost the entire SiC band gap are observable by means of x-ray photoelectron spectroscopy (XPS) measurements under bias, although SiC is a wide-gap semiconductor having 2.9 eV band-gap energy. When a SiO2 layer is formed by wet oxidation at 1000 degreesC on 6H-SiC(0001) Si-faced surfaces, only a broad interface state peak is observed at similar to2 eV above the SiC valence-band maximum (VBM), while for dry oxidation at the same temperature, an additional sharp interface state peak is caused at 1.8 eV above the VBM. When the wet-oxidation temperature is increased to 1150 degreesC, this 1.8-eV interface-state peak also appears. The concentration of graphitic carbon at the SiO2/SiC interface is found to increase with the heat treatment temperature. The 1.8-eV interface-state peak is tentatively attributed to graphitic carbon with a special structure near the interface. On the other hand, the broad 2-eV interface-state peak is attributed to Si dangling bonds at the interface. Without the 1.8-eV interface-state peak, current-voltage (I-V) curves measured under x-ray irradiation deviate only slightly from the ideal I-V curve (similar to0.4 V), while with this peak, the deviation becomes much larger (similar to0.8 V). XPS measurements under bias show that the I-V curves under x-ray irradiation are determined by the magnitude of band bending in SiC. Therefore, the deviation from the ideal I-V curve is attributed to the accumulation of holes (i.e., minority carriers), generated by x-ray irradiation, at interface states with energies between the SiC and metal Fermi levels, causing a downward SiC band-edge shift and thus resulting in a decrease in the magnitude of band bending in SiC. This result demonstrates that the interface states affect I-V characteristics by a static effect (i.e., interface state charges), not by a dynamical effect (i.e., electron-hole recombination at the interface states).