Abstract

The impact of DC off-state and AC gate + off-state stress on the time dependent dielectric breakdown (TDDB) of ultra-short channel high-k/metal gate (HKMG) nMOSFETs was investigated. Under high DC off-state (drain) bias, the dielectric wear out was found to be caused by hot hole injection at the drain side. The breakdown time scaled with the gate length in accordance with a higher impact ionization rate by an increased subthreshold leakage current for shorter channels. At identical bias, drain-only stress results in a less severe degradation in comparison to gate-only stress. However, the combination of alternating gate and off-state stress results in a lower lifetime compared to DC and AC gate-only stress. The AC gate + off-state pattern exhibits a similar degradation behavior as bipolar AC stress, attributed to continuous charge trapping and detrapping in the gate oxide. The TDDB failure distribution did not obey the Poisson area scaling assuming randomly generated defects. The spatial asymmetric breakdown localized at the drain edge could be described applying a more general negative binominal yield model.