In this paper, the effects of an open defect resulting in floating gate on combinational logic gate structures are studied. From this study, a novel method is derived to predict and narrow down the potential open defect location from a long failure path that is driving multiple branches of input nodes, into a much smaller segment without EBAC analysis. This method is applied with great success to localize open defects on actual low yield cases from advanced technology nodes with significant reduction in FA cycle time.

This paper describes the effectiveness of using light induced Current Imaging – Atomic Force Microscopy (CIAFP) to localize defects that are not easily detected through conventional CI-AFP. Defect localization enhancement for both memory and logic failures has been demonstrated. For advanced technology nodes memory failures, current imaging from photovoltaic effects enhanced the detection of bridging between similar types of junctions. Light induced effects also helped to improve the distinction between gated and nongated diode, as a result enhanced localization of gate to source/drain short.

The case study in this paper describes how collaboration between customer design and test teams and a thorough FAB investigation triggered by a detailed electrical analysis using the Atomic Force Nanoprober (AFP) resulted in the effective resolution of a challenging implant related issue on LDMOS structure that caused yield loss. The quick success in this case has led to a shorter yield ramp cycle on this new product for mass production.

Conductive-Atomic Force Microscopy (C-AFM) is a popular failure analysis method used for localization of failures in Static Random Access Memory (SRAM) devices [1-4]. The SRAM structure has a highly repetitive pattern where any abnormality in a failed cell compared to neighboring cells could be easily identified from its current image [5-7]. Unlike topographical imaging, the C-AFM requires the probe tip to be coated with a conductive layer in order to pick up the electrical signals from the device under test. The coating needs to be sufficiently thick as it would wear off after a certain amount of physical scanning. This additional coating on the AFM tip is essential but poses a limit to the tip radius curvature. The commercially available tip radius is approximately 35nm (DDESP-10 from Bruker) and the dimension is too large for imaging of 20nm technology device. However, the limitation could be alleviated by subjecting the sample surface to treatment prior to C-AFM imaging. The aim of this surface treatment is to ensure C-AFM tip maintains sufficient scanning contact with the tiny conductive (tungsten) structure of the sample in order to achieve distinct current image. The surface treatment is done by creating a receding Inter-Layer Dielectric (ILD) from its neighboring tungsten contact. The creation of the receding depth could be achieved by either wet etching or dry etching (Reactive Ion Etching, RIE). In this work, the surface treatments by these two methods have been investigated and the recipe is optimized to obtain a clear current image. The optimized recipe is then applied on actual failure analysis where three cases are studied.