Title :
Mechanism of Stress Memorization Technique (SMT) and Method to Maximize Its Effect
Author :
Pandey, S.M. ; Liu, J. ; Hooi, Z.S. ; Flachowsky, S. ; Herrmann, T. ; Tao, W. ; Benistant, F. ; See, A. ; Chu, S. ; Samudra, G.S.
Author_Institution :
Technol. Dev. Dept., Globalfoundries, Singapore, Singapore
fDate :
4/1/2011 12:00:00 AM
Abstract :
A simple and unified fundamental theory on the mechanism of stress memorization technique (SMT) is presented for the first time. This theory is based on the difference in thermal properties of the materials involved in SMT process, i.e., silicon (channel), polysilicon (gate), amorphous silicon (source/drain), SiO2 (gate oxide), as well as Si3N4 (SMT nitride stressor layer), which lead to deformations during thermal anneal and SMT. This theory accounts for all the results published to date in SMT and provides important physical insights. As a demonstration of predictive capability of this theory, a 45-nm process was modified using a novel anneal sequence which raises the stress in the channel. The experimental data after the change yield additional 5% performance boost for NFET compared to a baseline SMT process.
Keywords :
annealing; deformation; field effect transistors; NFET; deformations; nitride stressor layer; stress memorization technique; thermal annealing; thermal properties; Annealing; Logic gates; Performance evaluation; Silicon; Stress; Thermal expansion; Laser annealing (LSA); TCAD; stress; stress memorization technique (SMT);
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2011.2108634
