Scanning microwave impedance microscopy (sMIM) is a relatively new method for making electrical measurements on test samples in AFMs. This article presents examples in which sMIM technology is used to measure dielectric coefficients, doping concentrations, and nanoscale C-V curves for different semiconductor and dielectric materials. It also explains how measured results compare with theoretical models, confirming the validity of each approach.

Scanning microwave impedance microscopy is a nearfield technique using microwaves to probe the electrical properties of materials with nanoscale lateral resolution.

Scanning microwave impedance microscopy (sMIM) is an electrical measurement technique that can be used to determine dopant profiles in semiconductor devices. This article describes the basic setup and implementation of the method and demonstrates its use in the cross-sectional analysis of NMOS power transistors.

Scanning probe microscopy (SPM) is widely used for fault isolation as well as diagnosing leakage current, detecting open circuits, and characterizing doping related defects. In this article, the author presents two SPM applications that are fairly uncommon but no less important in the scope of failure analysis. The first case involves the discovery of nano-steps on the surface of high-voltage NFETs, a phenomenon associated with stress-induced crystalline shift along the (111) silicon plane. In the second case, the author uses an AFM probe in the conductive mode to correlate tunneling current distribution with hot spots in high-k gate oxide films, which is shown to be a better indicator of oxide quality than rms surface roughness.

This article demonstrates the value of atomic force microscopes, particularly the different electrical modes, for characterizing complex microelectronic structures. It presents experimental results obtained from deep trench isolation (DTI) structures using SCM and SSRM analysis with emphasis on the voltage applied by the AFM. From these measurements, a failure analysis workflow is proposed that facilitates AFM voltage optimization to reveal the structure of cross-sectioned samples, make comparisons, and determine the underlying cause of failures.

Sample preparation is a critical step for dopant profiling of FinFET devices, especially when targeting individual fins. This article describes a sample-preparation technique based on low-energy, shallow-angle ion milling and shows how it minimizes surface amorphization and improves scanning capacitance microscopy (SCM) signals representative of local active dopant concentration.

This article provides a recap and summaries of the EDFAS Virtual User Group Workshop held in January 2021. The summaries cover key participants, presentation topics, and discussion highlights from the Focused Ion Beam, Sample Preparation, Contactless Probing and Nanoprobing, and System on Package virtual group meetings.

Failure analysis labs are fairly well equipped for dealing with shorts and leakages in stacked-die packages, but are at a disadvantage when it comes to opens, particularly those at the die or die interconnect level. This article presents a new FA technique that has the potential to make up for this shortcoming. The new method, called space domain reflectometry (SDR), is based on radio-frequency magnetic current imaging, and as the authors show, is capable of accurately locating a dead open in a double-stacked BGA package, even when the full stack is encapsulated in molding compound.

The power of scanning optical microscopes (SOMs) lies in their ability to direct a small spot of light into an IC, producing photocarriers and heat in a localized area of the circuit. Photonic and thermal energy affect the I-V characteristics of the circuit in different ways, depending on the presence of defects and local material properties. This article explains how light beams interact with semiconductors and metals and how they influence the I-V characteristic of circuits and devices. It describes the basic physics of SOM measurements, provides examples of static and dynamic SOM techniques, and discusses emerging applications.

This column provides a ten-year retrospective on laser-based fault isolation techniques and the important role of laser signal injection microscopes.

This article describes how physical attacks can be launched on different types of nonvolatile memory (NVM) cells using failure analysis tools. It explains how the bit information stored inside these devices is susceptible to read-out and fault injection attacks and defines vulnerability parameters to help quantify risks associated with different modalities of attack. It also presents an in-depth security analysis of emerging NVM technologies and discusses potential countermeasures.

The 22nd European Symposium on Reliability of Electron Devices, Failure Physics and Analysis (ESREF 2011) was held October 3 to 7, 2011, in Bordeaux, France. The conference concentrated on two main areas in electronics that concern designers, manufacturers, and users: (1) strategy for quality and reliability assessment of electronic circuits and systems, and (2) advanced analysis techniques for technology and product evaluation. This article reports on highlights of the technical program.