That tapping is generally done at the resonant frequency of the probe. A stiff silicon tapping probe has a resonant frequency on the order of 300 kHz, and so a tapping frequency just below resonance is selected for tapping AFM. Constraining the tapping causes the probe frequency to increase, and this will cause the probe frequency to move towards resonance not off resonance.
While this mode of imaging produces minimal shear force, one disadvantage is that it produces an indeterminate maximum normal force. While one can image in soft tapping mode by reducing the tapping amplitude, it is a non-trivial task to estimate the maximum peak normal force in tapping AFM. It is sometimes also desirable to know the maximum force exerted on a sample to quantitate sample deformation.
Bruker's PeakForce tapping combines the best of tapping and contact AFM imaging modes. What it does is perform complete force curves at 1-2 kHz at every image point. The force curve is triggered at the maximum applied normal force according to these force curves, and it is this "PeakForce" that is the set-point or parameter maintained constant during imaging. The second image, borrowed from Bruker, shows force curves as a function of time and position, and the PeakForce set-point is point C on both curves. A further innovation is ScanAsyst technology which dynamically and intelligently monitors and optimizes the scan rate, PeakForce set-point, gains, and Z-limit to produce the best image quality.
In this image human collagen from cadaver skin was imaged using a ScanAsyst Air probe in ScanAsyst mode. This image of a fairly soft biological specimen was imaged with little operator interaction beyond aligning the scanner and focusing on the sample. An additional advantage of the PeakForce tapping imaging mode is that force curves are available at every image point, and these can be used to perform nanomechanical measurements-- what is called PeakForce QNM.
No comments:
Post a Comment