We demonstrate the effectiveness of combining top-down and cross-sectional electron beam induced current (EBIC) imaging with SEM nanoprobe analysis to identify subtle front-end defects in advanced FinFET technology. Our approach successfully localized a novel fin nanocrack defect that had previously eluded detection through conventional TEM imaging. This systematic resistive pMOS failure, observable only in memory arrays at 150°C, exemplifies the power of EBIC as an alternative to scanning capacitance microscopy for detecting dopant anomalies and subtle defects. The sample preparation and EBIC methodologies presented here are broadly applicable across CMOS technologies, offering a versatile approach to defect analysis.

In this work, we present three case studies that highlight the novelty and effectiveness of using multiple plasma FIB trenches to simultaneously access multiple metal layers for nanoprobing failure analysis. Multilayer access enabled otherwise impossible two-tip current imaging techniques and allowed us to fully characterize suspect logic gate transistors by exposing internal nodes, while preserving higher metal inputs and outputs. The presented case studies focus on late node planar and established FinFET technologies. The delayering techniques used are not necessarily technology dependent, but highly scaled and advanced processes generally require smaller trench areas for multilayer access. The minimum trench dimensions are limited by ion beam imaging resolution and trench-nanoprobe tip geometry.

Presentation slides for the ISTFA 2023 Tutorial session “LADA and SDL-Powerful Techniques for Marginal Failures (2023 Update).”