Title :
Methodology for Determination of Process Induced BTI Variability in MG/HK CMOS Technologies Using a Novel Matrix Test Structure
Author_Institution :
Globalfoundries, Inc., Yorktown Heights, NY, USA
Abstract :
Process variations in addition to random stochastic variations contribute to variability in aggressively scaled CMOS devices. To decouple the process variation from the random stochastic variations, a novel transistor test structure utilizing a matrix configuration is introduced. Based on this structure, it is shown that the local VT and local bias temperature instability (BTI)-induced variance scales inversely with the gate oxide area over a range of 1000x, whereas process variations lead to saturation in the variance when determined using samples across the wafer. The gate area dependence of the VT and the BTI-induced variance can be modeled independently using two stochastic processes.
Keywords :
CMOS integrated circuits; semiconductor device reliability; stochastic processes; CMOS technologies; aggressively scaled CMOS devices; local bias temperature instability; matrix configuration; matrix test structure; process induced BTI variability; random stochastic variations; stochastic processes; transistor test structure; CMOS integrated circuits; Field effect transistors; Logic gates; Metals; Monitoring; Reliability; Stochastic processes; Bias temperature instability (BTI); CMOS devices; high-$k$ dielectrics; metal gate; process variability; stochastic variability;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2014.2298096
