The charging and discharging of stress-generated traps inside thin silicon oxide

Abstract

Excess high-voltage stress-generated low-level leakage currents through 10 nm silicon oxides, previously described as DC currents, are shown to decay to the limit of detection given adequate observation time and, thus, have no discernible DC component. A physical model is presented which describes the majority of the excess low-level leakage currents in terms of the charging and discharging of traps previously generated by the high voltage stress. Excess low-level leakage currents measured with voltage pulses with polarity opposite to that of the stress voltage are found to contain an additional current component, which is explained by the transient charging and discharging of certain traps inside of the oxide. Evidence is presented which suggests that an oxide trap generated by the high-voltage stress can contain either a positive or a negative charge, in addition to being neutral and that the traps are located near both oxide interfaces. All of the trap charging and discharging currents can be explained by the flow of electrons into and out of traps generated by the high voltage stress, without resorting to the flow of holes in the oxide.