Advanced orientation mapping using precession 4D STEM  

Understanding the processing-structure-property relations in nanocrystalline materials has been the main interest of researchers because of their excellent mechanical properties linked with the microstructure. Transmission electron microscopy (TEM) is the most widely used technique because it has the necessary spatial resolution to resolve nanometer sized grains. However, in the case of conventional TEM orientation mapping, orientation and phase identification are often unreliable due to the low sensitivity and ambiguity of spot diffraction patterns. In addition, the acquisition of diffraction data by external charge coupled device (CCD) cameras introduces additional artifacts obstructing orientation and phase identification and requires redundant post image processing such as distortion and inclination corrections.

In this project, we optimize scanning nanobeam diffraction based orientation mapping.  In order to obtain high quality diffraction datasets, we utilize an in-column CMOS camera which is free from distortion and inclination corrections. The large field of view and high dynamic range of the CMOS camera largely enhances even faint details in the diffraction patterns. In combination with PED, the interpretability of each diffraction pattern is improved by increasing the number of diffraction spots and reducing dynamical diffraction effects. Figure 1 shows orientation mapping results of nanoscratched single crystal Si obtained by conventional and optimized process, respectively. Compare to conventional method (Fig. 1b), optimized process minimizes artifacts introduced by the acquisition system (Fig. 1c). Once the optimized scheme is established, we will extend the technique to strain mapping in conjunction with in situ deformation experiments to gain insight into the dynamic strain evolution in nanomaterials. The highly complex datasets of several hundreds of GBs impose another grand challenge that is currently tackled by developing automated routines for data analysis.