Title :
Comparative physical and electrical metrology of ultrathin oxides in the 6 to 1.5 nm regime
Author :
Ahmed, Khaled ; Ibok, Effiong ; Bains, Gurjeet ; Chi, David ; Ogle, Bob ; Wortman, Jimmie J. ; Hauser, John R.
Author_Institution :
Conexant Syst. Inc., Newport Beach, CA, USA
fDate :
7/1/2000 12:00:00 AM
Abstract :
In this work, five methods for measuring the thickness of ultra-thin gate oxide layers in MOS structures were compared experimentally on n+ poly-SiO2-p-Si structures. Three methods are based on electrical capacitance-voltage (C-V) and current-voltage (I-V) data and the other two methods are HRTEM and optical measurement. MOS capacitors with oxide thickness in the range 17-55 Å have been used in this study. We found that thickness extracted using QM C-V and HRTEM agree within 1.0 Å over the whole thickness range when a dielectric constant of 3.9 was used. Comparison between thickness extracted using quantum interference (QI) I-V technique and optical measurement were also within 1.0 Å for thickness 31-47 Å. However, optical oxide thickness was consistently lower than the TEM thickness by about 2 Å over the thickness range under consideration. Both optical measurement and QM C-V modeling yield the same thickness as the nominal oxide thickness increases (>50 Å)
Keywords :
MOS capacitors; semiconductor device measurement; thickness measurement; 6 to 1.5 nm; HRTEM; MOS capacitor; Si-SiO2-Si; capacitance-voltage characteristics; current-voltage characteristics; electrical metrology; ellipsometry; n+ poly-SiO2-p-Si structure; optical measurement; parameter extraction; physical metrology; quantum interference; quantum mechanical effect; thickness measurement; ultrathin gate oxide; Capacitance measurement; Capacitance-voltage characteristics; Current measurement; Data mining; Dielectric constant; Dielectric measurements; Electric variables measurement; MOS capacitors; Metrology; Thickness measurement;
Journal_Title :
Electron Devices, IEEE Transactions on
