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Consider one of the solution methods to the probe's tip equation of motion in an arbitrary potential  (see formula (1) in chapter 2.4.1). Assume the tip of length  is attached to the cantilever end as depicted in Fig. 1.
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| Fig. 1. Problem formulation. |
If the free cantilever beam end is excited and oscillates with amplitude  and frequency  at some height  above a sample surface, i.e.  , the tip equation of motion is given by
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(1) |
where  – cantilever effective mass,  – Q-factor,  – cantilever stiffness (see (10) in chapter 2.1.2),  – cantilever resonant frequency,  – probe-sample interaction potential,  – probe-sample distance.
From condition  one can easily determine the tip equilibrium position which is a certain function of  . Upon changing the variables  and  , the equation of motion is transformed to the following
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(2) |
where  and  . As the cantilever natural frequency is  , equation (2) can be written as:
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(4) |
where
and  – some small parameter ( ).
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(3) |
Introducing a new parameters designation, equation (3) takes the following form:
Solution of equation (4) for the case  and  can be obtained with the help of Krilov-Bogolyubov-Mitropolsky (KBM) method [1] which is a kind of perturbation theory.
If the solution of (4) is supposed to differ slightly from that for the harmonic oscillator, i.e.  with  and  , the functions  and  must meet the following conditions (to within the first order terms  ):
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(6) |
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where we introduced the auxiliary function  determined by the probe-sample interaction potential:
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(7) |
For the certain class of equation (4) solutions, the cantilever end's motion is a simple harmonic motion with fixed values of and . These fixed values are the critical points of equations (8) and (9) for the case when condition  is met. Using this condition, the following equations set can be written
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(8) |
Eliminating variable
from the set (8), the oscillation amplitude dependence on the
frequency, i.e. the system amplitude-frequency characteristic (AFC),
can be obtained:
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(9) |
This relation is
not explicit and can not be calculated in a general form. However,
using methods of numerical solution of explicit equations, the given
system AFC for the specific probe-sample interaction potential can be
calculated. In [2] such a calculation was performed assuming that potential is the Lennard-Jones potential that is written as:
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(10) |
Typical system AFCs as a function of probe-sample distance are shown in Fig 2a. The same relations obtained by the numerical solution of the differential equation of motion (1), are depicted in Fig. 2b for comparison.
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| Fig. 2. Comparison of the tip-sample system
AFC calculated using perturbation theory and numerical integration of
the motion equation [2]. |
As is seen from the
picture, when moving away from the sample surface (reduction of the
interaction potential), the AFC curves approach these of the simple
harmonic oscillator. The closer the tip is to the sample, the more
distorted are the resonance curves. Notice that situations are
available when a few stable amplitudes determined by starting
conditions correspond to one driving frequency.
From (8) one can find the phase-frequency characteristic (PFC) of the system noticing that the following is true for :
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(11) |
This
expression unambiguously relates the phase of oscillation to the
amplitude. Thus, once system AFC is calculated, the PFC can be easily
obtained using (11).
Summary.
- Theoretical technique of cantilever
motion equation analysis is described. This method is correct for
arbitrary driving force amplitude.
- If small oscillation condition is
not satisfied (probe-sample interaction force varies very abruptly
during oscillations amplitude), it is possible to exist several stable
solution (state). The state choice depends on initial conditions at
given driving frequency.
- Resonance characteristics of probe-sample system is given (9, 11) at arbitrary interaction potential .
References.
- N. Bogolyubov and Y.A. Mitropolsky, Asymptotic Methods in the
Theory of Nonlinear Oscillations. Gordan and Breach, New York, 1961.
- N. Sasaki and M. Tsukada, Appl.Surf.Sci. 140 (1999) 339-343.
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