This paper illustrated the beauty of AFP nanoprobing as the critical failure analysis tool in resolving the one-time programmable (OTP) non-volatile memory data retention failures through electrical simulation in wafer fabrication. Layout analysis, electrical simulation using Meilke’s method, UV erase methodology (to differentiate between mobile ion Meilke’s method contamination and charge trap centers) and a few other FA approaches were employed to determine the different root causes in the three OTP failure case detailed in this paper.. These include SiN trap center issue, poly stringers and abnormal layer at the initial CESL (Contact etch stop layer) nitride. This paper placed a strong emphasis on systematic problem solving approach, deep dive and use of right FA approach/tool that are essentially critical to FA analysts in wafer foundry since there is always minimal available data provided. It would serve as a good reference to wafer Fab that encountered such issue.

This paper placed a strong emphasis on the importance of applying Systematic Problem Solving approach, deep dive and use of right/appropriate FA approach/tools that are essentially critical to FA analysts to understand the “real” root cause. A case of low yield with polar failing pattern was seen and matched well with the Al Pad etch E chuck configuration. Customer also reported of passivation crack issue at the solder bumps. All these evidences suggested the root cause was related to wafer fabrication issue. However, it was through a strong “inquisitive” mindset coupled with the essence of such strong problem solving approach that led to uncover the actual root cause. Although customer test condition was not able to be duplicated due to limited information available in foundry industry, a four point probing alternative method was engaged to overcome this limitation. Unlike typical case, the AlOx thickness was comparable for bad and good dies. Further in depth analysis subsequently revealed the higher O content in the AlOx for the bad dies that was the real culprit for the higher bump resistance. This paper highlights the job of FA analyst is not simply finding defect but also plays a catalyst role in root cause/failure mechanism understanding by providing supporting FA evidence (electrically / physically) to Fab. It would serve as a good reference to wafer Fab that encountered such issue.

This paper places a strong emphasis on the importance of applying Systematic Problem Solving approach and use of appropriate FA methods and tools to understand the “real” failure root cause. A case of wafer center cluster RAM fail due to systematic missing Cu was studied. It was through a strong “inquisitive” mindset coupled with deep dive problem solving that lead to uncover the actual root cause of large Cu voids. The missing Cu was due to large Cu void induced by galvanic effects from the faster removal rate during Cu CMP and subsequently resulted in missing Cu. This highlights that the FA analyst’s mission is not simply to find defects but also play a catalyst role in root cause/failure mechanism understanding by providing supporting FA evidence (electrically/ physically) to Fab.

With the shrinkage of the IC device dimensions, Cu and ultra-low-k dielectric were introduced into IC devices to reduce RC delay. Ultra-low-k dielectrics generally suffer more damage than silicon oxide dielectric during process integration and subsequently cause reliability degradation. Therefore, ultra-low-k damage characterization on Cu damascene structures is of great importance to understand the damage mechanisms. This paper describes the application of UV-Raman microscopy with enhanced spatial resolution and signal sensitivity for characterizing ultra-low-k dielectric in the three-dimension structure of Cu metallization with nanometer feature size. It shows UV-Raman technique has an advantage in analyzing ultra-low-k layer on patterned wafer and extracting ultra-low-k signals from Cu/ultra-low-k mixed structure. UV-Raman is also effective to characterize the ultra-low-k degradation for ultra-low-k related reliability analysis by time dependent dielectric breakdown (TDDB) test.

Focused Ion Beam is widely used in semiconductor industry for critical applications such as TEM sample preparation and circuit edit. In this paper, we introduce an automated failure analysis technique for high precision polishing at the wafer level. Using FIB, it is possible to precisely mill at a region of interest, capture images at the region of interest simultaneously and cut into the die directly to expose the exact failure without damaging other sections of the specimen.