Focused ion beam (FIB) milling is a commonly used tool for nanoscale material processing, such as for transmission electron microscopy (TEM) sample preparation, or the creation of fiducial markers prior to other processes and measurements. During milling, a high energy ion beam is used to remove material via sputtering. The expelled target material may return to the sample surface however, affecting subsequent measurements. Beam spreading or irradiation due to neutral gallium may also irradiate a larger area than intended. Extensive research has explored the effects of FIB milling on the prepared TEM sample, but few have looked at the effects of milling on the properties of the sample surrounding the milled region. We use multiple pump‐probe laser‐based techniques (time domain thermoreflectance and steady‐state thermoreflectance) to measure the spatial extent of FIB‐induced surface/subsurface changes on a series of silicon wafers milled at multiple currents and doses. We supplement these measurements with high‐resolution scanning transmission electron microscopy, energy dispersive X‐ray spectroscopy, stylus profilometry, and time‐of‐flight secondary ion mass spectroscopy. We find a sample surface affected by the FIB up to 1 mm from where milling occurred, with a notable dependence on the ion beam current. We also note remarkably high sensitivity to surface defects using the thermoreflectance metrologies, including detection where other measurements failed.
Pfeifer et al. (Sun,) studied this question.