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Proceedings Papers
ISTFA2022, ISTFA 2022: Conference Proceedings from the 48th International Symposium for Testing and Failure Analysis, 347-351, October 30–November 3, 2022,
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Passive voltage contrast (PVC) is a well-known fault isolation technique in differentiating contrast at via/metal/contact levels while focused ion beam (FIB) is a destructive technique specifically used for cross sectioning once a defect is identified. In this study, we highlight a combination technique of PVC and progressive FIB milling on advanced node fin field-effect transistor (FinFET) for root cause analysis. This combo technique is useful when applied on high-density static random access memory (SRAM) structure, especially when it is difficult to view the defect from top-down inspection. In this paper, we create a FA flow chart and FIB deposition/milling recipe for SRAM failure and successfully apply them to three case studies.
Proceedings Papers
ISTFA2021, ISTFA 2021: Conference Proceedings from the 47th International Symposium for Testing and Failure Analysis, 269-273, October 31–November 4, 2021,
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Planar deprocessing is a vital failure analysis technique for semiconductor devices. The basic concept is to expose an area of interest (AOI) by removing unnecessary material while maintaining planarity and surface evenness. Finger deprocessing is a widely used material removal technique, particularly for fin field-effect transistors (FinFETs). Here, success depends on certain factors, one of which is the location of the AOI. If the AOI is near the edge of the chip, finger deprocessing can be very difficult because material removal rates are much higher there than at the center of the chip. Plasma focused ion beam (PFIB) planar deprocessing is the preferred solution in such cases, but many labs cannot afford a PFIB system. To address this challenge, a sample preparation method has been developed that uses dummy chips to effectively eliminate edges. With dummy chips placed edge-to-edge with test chips, planar deprocessing can be achieved using conventional finger deprocessing techniques. This paper describes the newly developed method, step by step, and presents two examples demonstrating its use.