In the model of Problem 14 94, what is the mechanical energy of the vibration when the tip is not interacting with the surface (a) 1 2 Atilde 10 18 J (b) 1 2 Atilde 10 16 J (c) 1 2 Atilde 10 9 J (d) 5 0 Atilde 10 8 J One technique for making images of surfaces at the nanometer scale, including memb...

IDENTIFY and SET UP The energy is constant so it is equal to the po ...

In the model of Problem 14.94, what is the mechanical energy of the vibration when the tip

Question:

In the model of Problem 14.94, what is the mechanical energy of the vibration when the tip is not interacting with the surface?

(a) 1.2 Ã— 10^-18 J;

(b) 1.2 Ã— 10^-16 J;

(d) 5.0 Ã— 10^-8 J.

One technique for making images of surfaces at the nanometer scale, including membranes and biomolecules, is dynamic atomic force microscopy. In this technique, a small tip is attached to a cantilever, which is a flexible, rectangular slab supported at one end, like a diving board. The cantilever vibrates, so the tip moves up and down in simple harmonic motion. In one operating mode, the resonant frequency for a cantilever with force constant k = 1000 N/m is 100 kHz. As the oscillating tip is brought within a few nanometers of the surface of a sample (as shown in the figure), it experiences an attractive force from the surface. For an oscillation with a small amplitude (typically, 0.050 nm), the force F that the sample surface exerts on the tip varies linearly with the displacement x of the tip, |F| = k_surf x, where k_surf is the effective force constant for this force. The net force on the tip is therefore (k + k_surf)x, and the frequency of the oscillation changes slightly due to the interaction with the surface. Measurements of the frequency as the tip moves over different parts of the sample€™s surface can provide information about the sample.

Sample surface Tip