DocumentCode :
1375260
Title :
Modified Percolation Model for Polycrystalline High- 
Gate Stack With Grain Boundary Defects
Author :
Raghavan, Nagarajan ; Pey, Kin Leong ; Shubhakar, Kalya ; Bosman, Michel
Author_Institution :
Sch. of Electr. & Electron. Eng., Nanyang Technol. Univ., Singapore, Singapore
Volume :
32
Issue :
1
fYear :
2011
Firstpage :
78
Lastpage :
80
Abstract :
We modify the existing oxide breakdown (BD) percolation model in this letter to account for the presence of microstructural weakest link grain boundary (GB) defects in polycrystalline high-κ (HK) gate stacks. The different rates of the stress-induced leakage current degradation and oxide trap generation at the bulk and GB regions need to be accounted for in modeling the statistical nature of BD in HK dielectric thin films. Simulated results reveal the dominance of GB-related failures and the origin of the non-Weibull stochastics inherent in polycrystalline HK stacks. We also point to the inability of conventional percolation models with an assumed uniform defect generation to describe the failure statistics of current HK gate stacks.
Keywords :
grain boundaries; high-k dielectric thin films; leakage currents; percolation; GB-related failures; HK dielectric thin films; failure statistics; microstructural weakest link grain boundary defects; modified percolation model; non-Weibull stochastics; oxide breakdown percolation model; oxide trap generation; percolation models; polycrystalline HK stacks; polycrystalline high-κ gate stacks; stress-induced leakage current degradation; uniform defect generation; Analytical models; Artificial neural networks; Dielectrics; Electric breakdown; Grain boundaries; Logic gates; Stochastic processes; Grain boundary (GB); high-$kappa$
fLanguage :
English
Journal_Title :
Electron Device Letters, IEEE
Publisher :
ieee
ISSN :
0741-3106
Type :
jour
DOI :
10.1109/LED.2010.2085074
Filename :
5629433
Link To Document :
