Abstract
We propose an experimental method to decompose the positive gate-bias stress (PBS)-induced threshold voltage shift ( $\Delta {V}_{\mathsf {th}})$ of amorphous InGaZnO (a-IGZO) thin-film transistors (TFTs) into the contributions of distinct degradation mechanisms. Top-gate self-aligned coplanar structure TFTs are used for this letter. Stress-time-divided measurements, which combine the subgap density-of-states (DOS) extraction and the analysis on recovery characteristics, are performed to separate the $\Delta {V}_{\mathsf {th}}$ components. Change in excess oxygen ( $\text{O}_{\mathsf {ex}})$ -related DOS is clearly observed, and $\Delta {V}_{\mathsf {th}}$ by PBS is quantitatively decomposed into the contributions of the active $\text{O}_{\mathsf {ex}}$ , and the deep and shallow gate insulator traps. The quantitative decomposition of PBS-induced $\Delta {V}_{\mathsf {th}}$ provides physical insight and key guidelines for PBS stability optimization of a-IGZO TFTs.
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