A re-evaluation of experimental results within the context of first-principles calculations strongly suggests that interface traps can contribute significantly to low-frequency (1/f ) noise in irradiated MOS devices. Hydrogen-induced trap activation and passivation are likely origins of the observed fluctuations. Measured and calculated activation energies for hydrogen drift, diffusion, and dissociation are consistent with energetics of 1/f noise. The dominant noise source is determined by densities of relevant defect precursors, hydrogen concentrations, device processing, and history. When present, hydrogen-induced interface-trap activation and passivation adds to noise due to border traps. These results should help assess and assure the performance and reliability of analog integrated circuits in high radiation environments.
Effects of Interface Traps and Hydrogen on the Low-Frequency Noise of Irradiated MOS Devices
Bonaldo S.
2024
Abstract
A re-evaluation of experimental results within the context of first-principles calculations strongly suggests that interface traps can contribute significantly to low-frequency (1/f ) noise in irradiated MOS devices. Hydrogen-induced trap activation and passivation are likely origins of the observed fluctuations. Measured and calculated activation energies for hydrogen drift, diffusion, and dissociation are consistent with energetics of 1/f noise. The dominant noise source is determined by densities of relevant defect precursors, hydrogen concentrations, device processing, and history. When present, hydrogen-induced interface-trap activation and passivation adds to noise due to border traps. These results should help assess and assure the performance and reliability of analog integrated circuits in high radiation environments.
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