Bulk oxide traps and border traps in metal–oxide–semiconductor capacitors

Thermally stimulated current (TSC) and capacitance–voltage measurements are combined via a newly developed analysis technique to estimate positive and negative oxide-trap charge densities for metal–oxide–semiconductor (MOS) capacitors exposed to ionizing radiation or subjected to high-field stress. Significantly greater hole trapping than electron trapping is observed in 3% borosilicate glass (BSG) insulators. Two prominent TSC peaks are observed in these BSG films. A high-temperature peak near 250 °C is attributed to the Eγ′ defect, which is a trivalent Si center in SiO2 associated with an O vacancy. A lower temperature positive charge center near 100 °C in these films is likely to be impurity related. The higher temperature Eγ′ peak is also observed in 10, 17, and 98 nm thermal oxides. A much weaker secondary peak is observed near ∼60 °C in some devices, which likely is due to metastably trapped holes in the bulk of the SiO2. Negative charge densities in these thermal oxides are primarily associated wit...

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