Title :
A simple visualizing technique of impurity diffusion layer using porous silicon phenomena
Author :
Yamaguchiya, N. ; Hirose, Y. ; Nakanishi, Naoya ; Maeda, Hideaki ; Yoshida, Erika ; Katayama, Takeo ; Koyama, Tomofumi
Author_Institution :
Process Integration Eng. Dept., Renesas Semicond. Eng. Corp., Itami, Japan
Abstract :
We propose an approach to visualize the impurity diffusion layer at a specific site in sub-100 nm CMOS devices using the porous silicon phenomena. This technique is based on electron microscope observations of samples which have been wet treated using self-aligned anodic oxidation in aqueous hydrofluoric acid. This can be applied to both NMOS transistors and PMOS transistors using the same procedure simultaneously in sub-100 nm CMOS transistors. A clear dopant distribution of source/drain and lightly doped drain (LDD) diffusion layers was obtained with not only transmission electron microscope, but also scanning electron microscope. This technique shows excellent reproducibility and stability, which have been critical issues with wet processing methods. In addition, a failure involving the highly-resistive electrical characteristics in the 90 nm-node transistor was analyzed. As a result, it was found that the failure was caused by a local block of LDD ion implantation. Our analysis revealed that visualizing the impurity diffusion layer using this technique can be applied to the fine CMOS devices at a specific site.
Keywords :
CMOS integrated circuits; MOSFET; impurities; ion implantation; semiconductor devices; CMOS transistors; NMOS transistors; PMOS transistors; aqueous hydrofluoric acid; dopant distribution; electron microscope observation; fine CMOS device; highly-resistive electrical characteristics; impurity diffusion layer; ion implantation; lightly doped drain diffusion layers; porous silicon phenomena; reproducibility; scanning electron microscope; self-aligned anodic oxidation; size 100 nm; size 90 nm; source/drain; stability; transmission electron microscope; visualizing technique; wet processing method; CMOS integrated circuits; CMOS technology; MOSFETs; Silicides; Silicon; Visualization; electron microscope; failure analysis; porous silicon phenomena; visualizing impurity diffusion layer; wet processing;
Conference_Titel :
Reliability Physics Symposium (IRPS), 2012 IEEE International
Conference_Location :
Anaheim, CA
Print_ISBN :
978-1-4577-1678-2
Electronic_ISBN :
1541-7026
DOI :
10.1109/IRPS.2012.6241784
