The global radio frequency (RF) semiconductor market size is growing dramatically in recent years, especially with the growing demand for mobile devices, communication networks, automotive applications, etc. Failure analysis (FA) on RF devices is normally more complex than digital devices, especially when it involves soft failure. This paper discusses FA on an RF product soft failure issue by the pulsed currentvoltage (IV) nanoprobing technique. The device suffered from high-frequency failure and exhibited abnormal repetitive softstart signature. Previous publications on pulsed IV nanoprobing applications were mostly related to Front End Of Line (FEOL) issues and simulations. In most of these cases, the electrical abnormality could also be observed with normal DC IV measurement. In this paper, the pulsed IV nanoprobing was performed at the Back End Of Line (BEOL) interconnects to isolate the failure that was otherwise not detected with normal DC nanoprobing or the reported pulse IV measurement. The proposed method successfully isolate, simulate the failure, and helping us to identify the process and design rule weakness.

With the scaling down of semiconductor devices to nanometer range, fault isolation and physical failure analysis (PFA) have become more challenging. In this paper, different types of fault isolation techniques to identify gross short failures in nanoscale devices are discussed. The proposed cut/deprocess and microprobe/bench technique is an economical and simple way of identifying low resistance gross short failures.

Electrical Test (ET) structures are used to monitor the health and yield of a process line. With the scaling down of semiconductor devices to nanometer ranges, the number of metal lines and vias increase. In order to simulate the electrical performance of devices and to increase the sensitivity for line health check, ET structures are designed to be more complicated with a larger area. Hence, fault isolation and failure analysis become more challenging. In this paper, the combined technique of Scanning Electron Microscope (SEM) Passive Voltage Contrast (PVC), Nanoprobing technique, and Divide and Conquer Method (DCM) are proposed to locate open failure and high resistance failure in an ET via chain.

With the scaling down of semiconductor devices to nanometer range, physical failure analysis (PFA) has become more challenging. In this paper, a different method of performing PFA to identify a physical vertical short of intermetal layer in nanoscale devices is discussed. The proposed chemical etch and backside chemical etch PFA techniques have the advantages of sample preparation evenness and efficiency compared to conventional PFA. This technique also offers a better understanding of the failure mechanism and is easier to execute in identifying the vertical short issue.

As electronic devices shrink further in the nanometer regime, electrical characterization using nanoprobing has become increasingly important. Focused ion beam (FIB) is one useful technique that can be used to create markings for ease of defective site identification during nanoprobing. This paper investigates the impact of FIB exposure on the electrical parameters of the pull-up (PU), pull-down (PD) and pass-gate (PG) transistors of 6-Transistor Static Random Access Memory (6T SRAM) cells.