This paper presents a characterization approach to study Local Layout Effects (LLEs) in FinFET devices. Since mechanical stress is commonly used as a mobility booster in modern transistors, layout-induced stress modulation will cause changes in performance. To investigate devices sensitivities and magnitude of variation a set of test structures with a broad range of Design of Experiment (DoE) factors is proposed, focusing on two layout features: FinFET isolation (diffusion break) and Gate Cut isolation. The test structures were deployed on 7nm test chip as part of PDF Characterization Vehicle CV® and electrical results showed that the magnitude of investigated LLEs could be as high as 13%. TCAD simulation study performed on the designed test structures confirmed that the performance variability can be explained by modulation of the mechanical stress.
Layout experiments and test structures to characterize Local Layout Effects due to mechanical stress in FinFET transistors
Rossoni A.
;Kovacs-Vajna Z.;Quarantelli M.
2025-01-01
Abstract
This paper presents a characterization approach to study Local Layout Effects (LLEs) in FinFET devices. Since mechanical stress is commonly used as a mobility booster in modern transistors, layout-induced stress modulation will cause changes in performance. To investigate devices sensitivities and magnitude of variation a set of test structures with a broad range of Design of Experiment (DoE) factors is proposed, focusing on two layout features: FinFET isolation (diffusion break) and Gate Cut isolation. The test structures were deployed on 7nm test chip as part of PDF Characterization Vehicle CV® and electrical results showed that the magnitude of investigated LLEs could be as high as 13%. TCAD simulation study performed on the designed test structures confirmed that the performance variability can be explained by modulation of the mechanical stress.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
