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Efrat M. Raz
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Journal Articles
Journal: EDFA Technical Articles
EDFA Technical Articles (2001) 3 (2): 26–27.
Published: 01 May 2001
Abstract
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The combination of microcleaving and precision broad ion beam techniques allows failure analysts to prepare site-specific specimens for SEM analysis with 0.5 μm accuracy. Microcleaving, as the article explains, uses the cleaving characteristics inherent in single-crystal semiconductor substrates. Because the substrate has significantly more mass than the process layers, it dictates the overall cross-section quality and precision of the sample. The cleave loses no material, preserves the integrity of the designated area, and enables analysis of both sides of the cross-section. When the cleave is off-set due to a buried target or when debris lies on the surface of the cross-section, ion beam etching and coating are used to fine tune the cleave location and remove debris prior to SEM analysis.
Proceedings Papers
ISTFA1999, ISTFA 1999: Conference Proceedings from the 25th International Symposium for Testing and Failure Analysis, 103-107, November 14–18, 1999,
Abstract
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The rising demand in the semiconductor industry for higher spatial resolution in the analysis of device defects has focused attention on the use of transmission electron microscopy (TEM). However, conventional TEM sample preparation may be difficult and time-consuming, and depending on the operator may result in a low yield of quality specimens. One solution to this problem is the use of focused ion beam (FIB) milling for the final stage of TEM sample preparation. However, specimens have to be mechanically thinned prior to FIB processing, and the need to characterize specific devices requires a pre-FIB preparation method to isolate specific regions on the wafer. An innovative and automated solution that isolates specific devices and prepares TEM specimens for subsequent thinning by FIB has been developed. Based on controlled microcleaving technology, the system automatically performs the pre-FIB preparation in less than 30 minutes. An important added benefit is that the target area to be analyzed can be positioned at a specific distance from the sample edge, thereby facilitating the final FIB milling stage. The thinned specimen is automatically packaged for subsequent FIB processing and TEM. Details of the method and examples showing TEM results from tungsten filled vias are presented.