Time dependent dielectric breakdown physics - Models revisited

Abstract Time-Dependent Dielectric Breakdown (TDDB) models for silica(SiO 2 )-based dielectrics are revisited so as to better understand the ability of each model to explain quantitatively the generally accepted TDDB observations. Molecular dielectric degradation models, which lead to percolation path generation and eventual TDDB failure, tend to fall into three broad categories: field-based models, current-based models, and complementary combinations of field and current-based models. A complementary combination of field-induced polar-bond stretching and current-induced bond-catalysis seems to be required, at the molecular level, to explain the generally accepted TDDB observations. Thus, TDDB modeling is not simply the use of field or current – but both. Complementary combinations of field and current are required to fully explain the generally accepted TDDB observations.

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