A novel physics-based variable NBTI simulation framework from small area devices to 6T-SRAM

Author

Naphade, T. ; Roy, Kaushik ; Mahapatra, Santanu

Author_Institution

Electr. Eng. Dept., Indian Inst. of Technol., Mumbai, Mumbai, India

fYear

2013

fDate

9-11 Dec. 2013

Abstract

A novel simulation framework is developed to study NBTI variability in devices and SRAM circuits. Stochastic Reaction Diffusion (RD) model for interface trap generation (ΔN_IT) and stochastic 2 well model for charging of pre-existing bulk traps (ΔN_HT) are interfaced with TCAD for electrostatics and time-zero variability to determine variable NBTI in device level. Distributions of ΔN_IT and ΔN_HT are generated for stress and recovery. ΔV_T and V_T distributions are generated using empirical exponential impact and full TCAD simulations. Simulated ΔV_T distributions match with experiments, analytic models and show correlation between mean and variance. Impact of NBTI variability on read, write and hold failure of 6T-SRAM is simulated by using SPICE. NBTI variability of these SRAM metrics is correlated to device V_T variability.

Keywords

SPICE; SRAM chips; circuit simulation; integrated circuit modelling; negative bias temperature instability; stochastic processes; technology CAD (electronics); 6T-SRAM circuit; RD model; SPICE; analytic models; bulk trap charging; electrostatics; empirical exponential impact; full TCAD simulations; interface trap generation; physics-based variable NBTI simulation framework; read-write hold failure; small area devices; stochastic 2 well model; stochastic reaction diffusion model; time-zero variability; Integrated circuit modeling; Predictive models; Resource description framework; Solid modeling; Stochastic processes; Stress; Three-dimensional displays;

fLanguage

English

Publisher

ieee

Conference_Titel

Electron Devices Meeting (IEDM), 2013 IEEE International

Conference_Location

Washington, DC

Type

conf

DOI

10.1109/IEDM.2013.6724746

Filename

6724746