Abstract-Degradation of p-MOSFET parameters during negative-bias temperature instability (NBTI) stress is studied for different nitridation conditions of the silicon oxynitride (SiON) gate dielectric, using a recently developed ultrafast on-the-fly I DLIN technique having 1-µs resolution. It is shown that the degradation magnitude, as well as its time, temperature, and field dependence, is governed by nitrogen (N) density at the Si/SiON interface. The relative contribution of interface trap generation and hole trapping to overall degradation as varying interfacial N density is qualitatively discussed. Plasma oxynitride films having low interfacial N density show interface trap dominated degradation, whereas relative hole trapping contribution increases for thermal oxynitride films having high N density at the Si/SiON interface.Index Terms-Device degradation, hole trapping, interface traps, negative-bias temperature instability (NBTI), on-the-fly (OTF) I DLIN , plasma oxynitride, p-MOSFETs, thermal oxynitride.
Abstract-In this paper, a simple phenomenological technique is used to isolate the hole-trapping and interface trap generation components during negative bias temperature instability (NBTI) stress in plasma nitrided oxide (PNO) p-MOSFETs. This isolation methodology reconciles the apparent differences between experimentally measured NBTI power-law time exponents obtained by ultrafast on-the-fly I DLIN method, which are the ones obtained using slightly delayed but very long-time measurements, and the corresponding exponents predicted by the reaction-diffusion model. A systematic validation of the isolation technique is provided through degradation data taken over a broad range of operating conditions and a wide variety of PNO processes, to establish the robustness and uniqueness of the separation procedure.Index Terms-Activation energy, field acceleration, hole trapping, interface traps, negative bias temperature instability (NBTI), plasma oxynitride, p-MOSFET, reaction-diffusion (R-D) model, time exponent.
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