Abstract
The distinction between point and line resolution in transmission electron microscopy (TEM) arises because an ability to image sub-0.2 nm fringes is a necessary, but not a sufficient, condition for imaging individual atoms. In scanned tip microscopy, as in TEM, empirical data on instrument response should precede assertions about point resolution. In the “slow scan limit”, time-domain noise and geometry effects decouple, and tip shape can take on the role of a two-dimensional impulse response function. We show here that nuclear track pits can be used to quantitatively measure tip geometry with nanometer-scale resolution in three dimensions, that stationary tip images provide a robust measure of time-domain instabilities, and that when these data are taken before and after imaging an unknown, images with instrument response quantitatively constrained by experiment are possible. Specimen-induced tip effects also become measurable in situ.
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