Normally-off 4H-SiC MOSFETs are used to build NMOS logic gates intended for high temperature operation. The logic gates are characterized between 25°C and 500°C. Stable gate operation for more than 200h at 400°C in air is demonstrated. The excellent MOS reliability is quantified using I-V curves to dielectric breakdown and constant voltage stress to breakdown at 400°C. Although the effective tunneling barrier height B for electrons lowers to 2eV at 400°C, the extrapolated lifetime from constant voltage stress to breakdown measurements is longer than 105h at 400°C for typical logic gate operating field strength of 2MV/cm.
We investigated the performance of different metallization/passivation systems for high temperature applications. The metallizations comprised a 150 nm sputtered Pt or a 150 nm e-beam evaporated PtRh layer on Ti/TiN underlayers, respectively. The passivation coatings consisted of amorphous PECVD SiOx, of amorphous stress-reduced PECVD SiNy, and of a SiOx/ SiNy stack. For samples with SiOx and SiOx/ SiNy passivation layers the electrical properties changed after a short high temperature anneal at 600 °C but then remained stable during further annealing. This was attributed to the formation of PtTi alloys, which stabilized the metallization stack. In samples with SiNy passivation a significant Pt out-diffusion into the passivation layer was observed. This led to a degradation of the electrical and mechanical properties. The best performance was achieved with Pt-based metallizations and SiOx or SiOx/SiNy passivations.
The suitability of normally-off 4H-SiC MOSFETs for high temperature operation in logic gates is investigated. Fowler-Nordheim analysis shows a lowering of the effective tunneling barrier height at elevated temperatures. Trap assisted tunneling induced by carbon interstitials is proposed as the responsible mechanism. Nevertheless, reliability of MOS devices even at 400°C is excellent with an extrapolated critical field of 2.69MV/cm for a 10 year time to dielectric breakdown. The switching behavior of logic gates is also characterized between 25°C and 400°C. Using these logic gates, a fully integrated edge triggered flip-flop is build and high temperature operation is demonstrated.
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