Electron trapping in buried oxides during irradiation at 40 and 300 K

Abstract

The formation of electron traps has been studied in thermally grown silicon dioxide that was encapsulated by polysilicon and annealed at temperatures from 1100 to 1325/spl deg/C. Samples with oxide thicknesses of 100 and 400 nm were examined by cryogenic and room temperature detrapping measurements. Two distinct electron traps were observed in buried oxides; the thermal trap depths are 0.5 and 1.1 eV and the tunneling depths are 0.9 and 1.5 eV. The deeper electron trap is filled by room temperature irradiation. The deeper trap is detrapped by thermal excitation between room temperature and 120/spl deg/C or by tunneling at fields between 4 and 5 MV/cm. The formation of both electron traps is diffusion limited and the Si/SiO/sub 2/ interfaces are the source or sink for the diffusing species. While shallow trap formation monotonically increases with annealing temperature, trapping in the deeper trap peaks at about 1200/spl deg/C for the 400 nm thickness and at 1100/spl deg/C or lower for the 100 nm thickness. The occupation of shallow traps during cryogenic irradiation decreases the occupation of the deeper trap compared with room temperature irradiation. At high concentrations, the shallow traps decrease the tunneling field of the deeper trap by trap-assisted tunneling.