This paper reports optimized Transmission Electron Microscopy (TEM) sample preparation methods with Focus Ion Beam (FIB), which are used to reduce or avoid the overlapping of TEM images. Several examples of optimized cross-section sample preparation on 38nm and 45nm pitch are provided with general and novel FIB methods. And its application to plan view TEM sample preparation is also shown. The results establish that the proposed method is useful to reduce or remove pattern overlapping effects in dense structures and can produce higher quality TEM images than can be obtained using conventional top-down FIB-based TEM preparation methods.

It has been reported that a sample prepared by ion beam milling has a sandwich structure with amorphous on two sidewalls and crystal in the middle. In this paper, the sandwich structure of such a single crystal TEM sample was studied experimentally. A novel sample and its fabrication process were reported. The sandwich structure can be observed directly in TEM with this sample. When the crystal layer in monocrystal silicon TEM sample is less than 18 nanometers, or when the sample is thinner than 64 nanometers, the sample will be observed as fully amorphous. Removal of the amorphous layer on the sample sidewalls is crucial to get TEM pictures of better quality.

In this paper, a case of package level reliability test failure was studied. A model of “Slice Defect”, which was identified as the root cause by failure analysis, is introduced. Experiment results are presented to approve that such model is in fact correct and the corrective actions are effective.

In this paper, crystal damage on TEM sample sidewalls induced by FIB milling during sample preparation was studied. A novel method was invented to prepare the sample, which facilitates the direct observation of amorphous layers on the sidewall. The ion beam acceleration voltage is the dominant factor that affects the damaged layer thickness. The measured amorphous thickness is about 23 nanometers at 30Kv and 10 nanometers at 10Kv. The damage layer thickness is constant with different beam currents over the range from 30pA to 1000pA. Amorphous layer thickness also stays constant with the sample tilt angle.

This paper examines copper-interconnect integrated circuit transmission electron microscope (TEM) sample contamination. It investigates the deterioration of the sample during ion milling and storage and introduces prevention techniques. The paper discusses copper grain agglomeration issues barrier/seed step coverage checking. The high temperature needed for epoxy solidifying was found to be harmful to sidewall coverage checking of seed. Single beam modulation using a glass dummy can efficiently prevent contamination of the area of interest in a TEM sample during ion milling. Adoption of special low-temperature cure epoxy resin can greatly reduce thermal exposure of the sample and prevent severe agglomeration of copper seed on via sidewall. TEM samples containing copper will deteriorate when stored in ordinary driers and sulphur contamination was found at the deteriorated point on the sample. Isolation of the sample from the ambient atmosphere has been verified to be very effective in protecting the TEM sample from deterioration.