Operating temperature has a significant imp-act on the reliability of metal–oxide–semiconductor field effect transistors (MOSFETs). In Si-channel MOSFETs, the effective density of charged oxide defects ( $\Delta {N}_{\text {eff}}$ )… Click to show full abstract
Operating temperature has a significant imp-act on the reliability of metal–oxide–semiconductor field effect transistors (MOSFETs). In Si-channel MOSFETs, the effective density of charged oxide defects ($\Delta {N}_{\text {eff}}$ ) at operating condition typically shows an Arrhenius temperature dependence with ${E}_{\text {A}}$ ~ 0.1 eV. In contrast, apparent non-Arrhenius temperature dependence is reported here for InGaAs devices subjected to BTI stress in a wide range of temperature (77–373 K). This apparent non-Arrhenius temperature dependence is explained here by the presence of three distinct populations of electron traps. Capture–emission-time maps are derived from the experimental data, and are modeled by three bivariate distributions of energy barriers for the capture and emission processes. The total $\Delta {V}_{\text {th}}$ measured in bias-temperature-instability experiments reflects different contributions from the three defect populations, depending on the chosen temperature range, and on the measurement timing. We show that a correct description of the three defect distributions is crucial to properly assess their impact on the device performance.
