Implant related issues are hard to detect with conventional techniques for advanced devices manufactured with deep sub-micron technology. This has led to introduction of site-specific analysis techniques. This paper presents the scanning capacitance microscopy (SCM) technique developed from backside of SOI devices for packaged products. The challenge from backside method includes sample preparation methodology to obtain a thin oxide layer of high quality, SCM parameters optimization and data interpretation. Optimization of plasma etching of buried oxide followed by a new method of growing thin oxide using UV/ozone is also presented. This oxidation method overcomes the limitations imposed due to packaged unit not being able to heat to high temperature for growing thermal oxide. Backside SCM successfully profiled both the n and p type dopants in both cache and core transistors.

In the selection of ultra low k materials, process compatibility is a very important factor. Plasma processing plays a critical role in enhanced interconnect integration. It is therefore important to study plasma interaction with the ultra low k materials and its effects on the structure and property of these materials. X-ray reflectivity (XRR) measurement can be used to measure film thickness, density and interface roughness, which are important parameters to check for after plasma treatments. In the current study, porous SiLK (p-SiLK) was treated with various plasmas, such as O2, O2/N2, H2/N2, CH2F2/Ar and CF4/O2. XRR results indicate that the density of the p-SiLK films remains unchanged after various plasma treatments. Surface roughening occurs during the plasma treatments, accompanied by the decrease in film thickness. Plasma-induced surface roughening was also observed using atomic force microscope (AFM). Such roughening is more severe for plasma treatments using oxygen-containing plasmas. FTIR analysis indicates that the chemical structure of the p-SiLK films is not significantly affected by plasma treatment. It is reasonable to conclude that oxidation of the surface plays a major role in the plasma-induced change in surface roughness and film thickness.