New positive charge trapping dynamics in SiO2 gate oxide, based on bulk impact ionization processes under Fowler–Nordheim stress

A new charge trapping dynamics is proposed to analyze theoretically the gate oxide degradation in metal oxide silicon structures under Fowler–Nordheim (F–N) stress (6–10 MV/cm) at a low injected electron fluence. Devices studied were MOS capacitors with 22-, 27-, and 33-nm-thick, thermally grown silicon dioxide (SiO₂) on (100) n-Si. Our model includes tunneling electron initiated band-to-band impact ionization and trap-to-band ionization, as the possible mechanisms for the generation of hole and positive charge in the bulk of the oxide, respectively. The results from our model are in good agreement with the experimental results of gate voltage shift with injected electron fluence under constant current stress. Based on the developed coupled dynamics, we have compared the degradation under F–N stress at a constant current and gate voltage.