Title :
Physically Based Modeling of Stress-Induced Variation in Nanoscale Transistor Performance
Author :
Xu, Nuo ; Wang, Lynn Tao-Ning ; Neureuther, Andrew R. ; Liu, Tsu-Jae King
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Univ. of California-Berkeley, Berkeley, CA, USA
Abstract :
Uniaxial stress is widely used in advanced CMOS technologies to boost transistor performance. Conventional compact transistor models rely on empirical fitting of the average channel stress value to predict mobility and, hence, transistor performance. This approach can lead to significant errors for deeply scaled technologies. In this paper, stress profiles are modeled in analytical form, using a physically based approach. The stress model is validated by 3-D TCAD simulations. A nanometer-scale transistor intrinsic delay formula based on injection velocity theory is then applied. The predicted variation in transistor performance compares well with the measured silicon data for a 45-nm strained CMOS technology.
Keywords :
CMOS integrated circuits; MOSFET; electron mobility; nanoelectronics; semiconductor device models; technology CAD (electronics); 3D TCAD simulations; advanced CMOS technology; boost transistor performance; channel stress; conventional compact transistor models; deeply scaled technology; empirical fitting; injection velocity theory; nanometer-scale transistor intrinsic delay formula; nanoscale transistor performance; physically based approach; physically based modeling; predict mobility; predicted variation; silicon data; strained CMOS technology; stress model; stress profiles; stress-induced variation; uniaxial stress; Analytical models; Layout; Logic gates; MOSFETs; Semiconductor device modeling; Stress; Analytical model; injection velocity; layout-dependent variation; mobility; stress;
Journal_Title :
Device and Materials Reliability, IEEE Transactions on
DOI :
10.1109/TDMR.2011.2144598
