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Beilstein J. Nanotechnol. 2013, 4, 153–163, doi:10.3762/bjnano.4.15
Figure 1: Experimental tip–sample virial vts(z,asp) and dissipation ets(z,asp). Data acquired in vacuum on a ...
Figure 2: Plot of the normalized force sensitivity S × k/Q versus normalized amplitude a*/λ, where λ is the c...
Figure 3: Stability of the z control in FM in vacuum. Arrows indicate the direction of the motion of z when p...
Figure 4: High-resolution images of mica in water taken with FM, DAM and AM. FM (a) topography and (b) dissip...
Beilstein J. Nanotechnol. 2012, 3, 336–344, doi:10.3762/bjnano.3.38
Figure 1: The interaction versus distance. (a) Conservative force versus distance interaction between an AFM ...
Figure 2: Feedback diagrams for different d-AFM modes. dAFM has three basic variables: The oscillation amplit...
Figure 3: Testing the methods at high Q. Topography images of a calibration grid taken in vacuum in (a) AM (s...
Figure 4: Response to a step perturbation under high Q. (a) Perturbation applied to the free cantilever. (b) ...
Figure 5: In vacuum total dissipation (a) and frequency shift (b) curves as a function of the z-scanner posit...
Figure 6: Gold electrodes fabricated by e-beam lithography. The DAM topography was acquired in vacuum with ex...
Figure 7: DAM in liquid. Frequency shift (black) and dissipation (light gray) for a clean tip (a) and after b...