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The on-device and target-less overlay (OVL) measurement adds various challenges to the conventional target-based one.1 Most of the common solutions are based on the use of high voltage SEM to have a high resolution and see-through capabilities to see both layers entirely. To ensure repeatability and robustness the measurement is also generally realized on dedicated targets.2–4 Another approach is explored in this work : it consists of a direct measurement on the device itself, without any dedicated target and using a CD-SEM that do not have see-through capabilities. To avoid any damage on the final device and to ensure a partial vision of the bottom layer, the measurement is realized post etch. What can a true on-device, target-less, SEM overlay metrology reveal of the process? To answer this question, a custom design-based on-device CD-SEM overlay metrology was developed.5 It allows measuring the overlay on any bilayer 2D structure, even partially hidden, provided that sufficient edges are visible. Thanks to this post-processing capacity to measure on partially hidden patterns, the CD-SEMs from the current tool park can be used and non-transparent layers can be investigated. After demonstrating the capability of the previously mentioned solution on synthetic SEM images,6 by taking advantage of the versatility of the method and of an improved bilayer contour extraction algorithm, one product wafer was measured densely at different steps of the process on several patterns. These extensive measurements aim to reveal overlay signatures at different spatial frequencies: intra-field, intra-chip and even inside a random logic array. This paper details and interprets the observed overlay measurement with models while investigating the matching between the different measurement patterns and the mismatches with the optical overlay. To conclude, the contour-based metrology offers the capability to extract highly valuable information from CD-SEM images and represents a great opportunity for on-device overlay measurement. By measuring directly the products’ patterns, the developed metrology shows a mismatch between optical and SEM measurements up to a couple of nanometers. A hybrid model, mixing SEM and optical measurements reduced by 15% the on-product residuals. Additionally, the local overlay variability could be evaluated and low amplitude chip signatures have been observed. This new information will help process engineers to improve the process characterization, leading to a better process control that results in an improved reliability.
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