Title :
Gate stack resistance and limits to CMOS logic performance
Author :
Wachnik, Richard A. ; Lee, Sang-Rim ; Pan, L.H. ; Lu, Ning ; Li, Huaqing ; Bingert, R. ; Randall, Mai ; Springer, S. ; Putnam, Cynthia
Author_Institution :
IBM Semicond. R&D Center, Hopewell Junction, NY, USA
Abstract :
The input resistance of CMOS circuits is a measurable limit on the performance of typical static CMOS logic gates. A survey of measured data from five generations of CMOS technology including polysilicon oxynitride gate first stacks (P-SiON) high-K metal gate first stacks (GF) and high-K replacement metal gate stacks (RMG) shows a trend of increasing gate resistance. We show DC and RF measurements may be analyzed to determine horizontal and vertical components of gate resistance in terms of scalable parameters and the sum of these components may be represented by a compact scalable equation representing total gate resistance. Gate resistance increases at advanced nodes and affects typical logic performance of a 20nm replacement gate technology.
Keywords :
CMOS logic circuits; high-k dielectric thin films; integrated circuit measurement; logic gates; CMOS logic performance; P-SiON; gate stack resistance; high-K metal gate first stacks; high-K replacement metal gate stacks; polysilicon oxynitride gate first stacks; replacement gate technology; size 20 nm; static CMOS logic gates; CMOS integrated circuits; Electrical resistance measurement; Fingers; Logic gates; Metals; Radio frequency; Resistance;
Conference_Titel :
Custom Integrated Circuits Conference (CICC), 2013 IEEE
Conference_Location :
San Jose, CA
DOI :
10.1109/CICC.2013.6658494
