Electrical characterization is a critical step in the failure analysis workflow, a sequence that often ends in high-resolution imaging in the transmission electron microscope (TEM). Scanning TEM electron beam-induced current (STEM EBIC) is a technique that effectively combines these methods by performing electrical characterization at each imaging pixel, with the electron beam acting as a local current source. This work highlights the specimen preparation technique using the Ga FIB system followed by post-FIB Ar ion milling for STEM EBIC analysis. We present STEM EBIC as a technique to evaluate the surface quality of the specimens and to characterize the electronic properties of advanced devices at high resolution. With STEM EBIC, inactive and active finFET structures were clearly distinguished and improvements in sample quality from post-FIB Ar ion milling were evident.

Advanced memory technologies are in demand with phase change memory (PCM) devices as a forefront candidate. For successful characterization by transmission electron microscopy (TEM) for failure analysis and device development, an accurate and controllable thinning of TEM specimens is critical. In this work, TEM specimens from a GeTe-based PCM device at a partial SET state were prepared using a Xe plasma focused ion beam (pFIB) and polished to electron transparency using Ar ion beam milling. We will highlight the differences between Ga focused ion beam (FIB) and Xe pFIB TEM specimen preparation, the benefits of post-pFIB Ar ion beam milling, and show TEM results of the effects of partial SET programming of the GeTe PCM device.

Semiconductor devices are decreasing in dimensions and currently comprise stacks of ultrathin layers as in a spin-transfer torque magnetoresistive random-access memory (STTMRAM) device. For successful characterization by transmission electron microscopy (TEM) for failure analysis and device development, an accurate and controllable thinning of TEM specimens for is desirable. In this work, we combine plan view Ga focused ion beam (FIB) and post-FIB Ar milling preparation to prepare TEM specimens from a STT-MRAM device. Post-FIB Ar milling technique as a final polishing step of plan view TEM specimens was shown to prevent exposure of the tunnel barrier layer that can be damaged by the Ga FIB beam. We discuss the plan view FIB preparation, post-FIB Ar milling step and image analysis of the TEM images.

This paper describes an accurate and controllable delayering process to target defects in new materials and device structures. The workflow is a three-step process consisting of bulk device delayering by broad Ar ion beam milling, followed by plan view specimen preparation using a focused ion beam, then site-specific delayering via concentrated Ar ion beam milling. The end result is a precisely delayered device without sample preparation-induced artifacts suitable for identifying defects during physical failure analysis.

Fast and accurate examination from the bulk to the specific area of the defect in advanced semiconductor devices is critical in failure analysis. This work presents the use of Ar ion milling methods in combination with Ga focused ion beam (FIB) milling as a cutting-edge sample preparation technique from the bulk to specific areas by FIB lift-out without sample-preparation-induced artifacts. The result is an accurately delayered sample from which electron-transparent TEM specimens of less than 15 nm are obtained.

Transmission electron microscopy (TEM) specimens are typically prepared using the focused ion beam (FIB) due to its site specificity, and fast and accurate thinning capabilities. However, TEM and high-resolution TEM (HRTEM) analysis may be limited due to the resulting FIB-induced artifacts. This work identifies FIB artifacts and presents the use of argon ion milling for the removal of FIB-induced damage for reproducible TEM specimen preparation of current and future fin field effect transistor (FinFET) technologies. Subsequently, high-quality and electron-transparent TEM specimens of less than 20 nm are obtained.

The semiconductor industry is constantly investigating new methods that can improve both the quality of TEM lamella and the speed at which they can be created. To improve throughput, a combination of FIB-based preparation and ex situ lift-out (EXLO) techniques have been used. Unfortunately, the carbon support on the EXLO grid presents problems if the lamella needs to be thinned once it is on the grid. In this paper, we present low-energy (<1 keV), narrow-beam (<1 μm diameter), Ar+ ion milling as a method of preparing electron-transparent and gallium-free EXLO FIB specimens.

The sub-nanometer resolution that transmission electron microscopy (TEM) provides is critical to the development and fabrication of advanced integrated circuits. TEM specimens are usually prepared using the focused ion beam, which can cause gallium-induced artifacts and amorphization. This work presents the use of a concentrated argon ion beam for reproducible TEM specimen preparation using automatic milling termination and targeted ion milling of device features; the result is high-quality and electron-transparent specimens of less than 30 nm. Such work is relevant for semiconductor product development and failure analysis.