(Z) Coarse Z motion translator- This translator
moves the AFM head towards the surface so that the force sensor can
measure the force between the probe and sample. The motion of the
translator is usually about 10 mm.
(T) Coarse X-Y translation stage - The XY
translation stage is used to place the section of the sample that is
being imaged by the AFM directly under the probe.
(X-P) X and Y piezoelectric transducer - With the X
and Y piezoelectric transducer the (Y-P) probe is moved over the
surface in a raster motion when an AFM image is measured.
(FS) Force Sensor - The force sensor measures the
force between the probe and the sample by monitoring the deflection
of a cantilever.
(ZP) Z piezoelectric Ceramic - Moves the force
sensor in the vertical direction to the surface as the probe is
scanned with the X and Y piezoelectric transducers.
(FCU) Feedback control unit - The feedback control
unit takes in the signal from the light lever force sensor and
outputs the voltage that drives the Z piezoelectric ceramic. This
voltage refers to the voltage that is required to maintain a
constant deflection of the cantilever while scanning.
(SG) X-Y signal generator - The motion of the probe
in the X-Y plane is controlled by the X-Y signal generator. A raster
motion is used when an image is measured.
(CPU) Computer - The computer is used for setting
the scanning parameters such as scan size, scan speed, feedback
control response and visualizing images captured with the
microscope.
(F) Frame - A solid frame supports the entire AFM
microscope. The frame must be very rigid so that it does not allow
vibrations between the tip and the surface.
Note - Not shown, is an optical microscope that is
essential for locating features on the surface of the sample and for
monitoring the probe approach process.
Measuring images with an atomic force microscope
- Place a probe in the microscope and align the light lever
sensing system.
- With the X-Y sample and the optical microscope place the
region of the sample that will be imaged directly under the AFM
probe.
- Engage the Z translation stage to bring the probe to the
surface.
- Start the scanning of the probe over the surface and view the
image of the surface on the computer screen.
- Save the image on a computer disk.
Resolution in an atomic force microscope
Traditional microscopes have only one measure of
resolution; the resolution in the plane of an image. An atomic force
microscope has two measures of resolution; the plane of the
measurement and in the direction perpendicular to the surface.
In Plane Resolution: The in-plane resolution depends
on the geometry of the probe that is used for scanning. In general,
the sharper the probe is the higher the resolution of the AFM image.
In the Figure below is the theoretical line scan of two spheres that
are measured with a sharp probe and a dull probe.
Figure 6: The image on the right will have a higher
resolution because the probe used for the measurement is much
sharper.
Vertical Resolution: The vertical resolution in an
AFM is established by relative vibrations of the probe above the
surface. Sources for vibrations are acoustic noise, floor
vibrations, and thermal vibrations. Getting the maximum vertical
resolution requires minimizing the vibrations of the instrument.
Probe Surface Interactions
The strongest forces between the probe and surface
are mechanical, which are the forces that occur when the atoms on
the probe physically interact with the atoms on a surface. However,
other forces between the probe and surface can have an impact on an
AFM image. These other forces include surface contamination,
electrostatic forces, and surface material properties.
Surface contamination
In ambient air all
surfaces are covered with a very thin layer, < 50 nm, of
contamination. This contamination can be comprised of water and
hydrocarbons and depends on the environment the microscope is
located in. When the AFM probe comes into contact with the surface
contamination, capillary forces can pull the probe towards the
surface.
Electrostatic forces
Insulating surfaces
can store charges on their surface. These charges can interact with
charges on the AFM probe or cantilever. Such forces can be so strong
that they "bend" the cantilever when scanning a surface.
Surface material properties
Heterogeneous
surfaces can have regions of different hardness and friction. As the
probe is scanned across a surface, the interaction of the probe with
the surface can change when moving from one region to another. Such
changes in forces can give a "contrast" that is useful for
differentiating between materials on a heterogeneous surface.
Topography Modes
When scanning a sample with an AFM a constant force
is applied to the surface by the probe at the end of a cantilever.
Measuring the force with the cantilever in the AFM is achieved by
two methods. In the first method the deflection of the cantilever is
directly measured. In the second method, the cantilever is vibrated
and changes in the vibration properties are measured.
Deflection Mode
Using the feedback control in the AFM, it is
possible to scan a sample with a fixed cantilever deflection.
Because the deflection of the cantilever is directly proportional to
the force on the surface, a constant force is applied to the surface
during a scan. This scanning mode is often called "contact" mode.
However, because the forces of the probe on the surface are often
less than a nano-newton, the probe is minimally touching the
surface.
Figure 7: In contact mode AFM the probe directly
follows the topography of the surface as it is scanned. The force of
the probe is kept constant while an image is measured.
Vibrating Mode
The cantilever in an AFM can be vibrated using a
piezoelectric ceramic. When the vibrating cantilever comes close to
a surface, the amplitude and phase of the vibrating cantilever may
change. Changes in the vibration amplitude or phase are easily
measured and the changes can be related to the force on the surface.
This technique has many names including non-contact mode, and
intermittent contact mode. It is important that the tip not "tap"
the surface because the probe may be broken or the sample may be
damaged.
Figure 8: In vibrating methods, changes in probes
vibrations are monitored to establish the force of the probe onto
the surface. The feedback unit is used to keep the vibrating
amplitude or phase constant.
Material Sensing Modes
The interaction of the probe with the surface
depends on the chemical and physical properties of the surface. It
is possible to measure the interactions and thus "sense" the
materials at a sample's surface.
Vibrating Material Sensing Mode
As described in Section 3.2, the AFM cantilever may
be vibrated to measure the force between a probe and surface during
an AFM scan. The magnitude of amplitude damping and the amount of
phase change of the cantilever depends on the surface chemical
composition and the physical properties of the surface. Thus, on an
inhomogeneous sample, contrast can be observed between regions of
varying mechanical or chemical composition. Typically, in the
vibrating material sensing mode, if the amplitude is fixed by the
feedback unit, then the contrast of the material is observed by
measuring phase changes. This technique has many names including
phase mode, phase detection and force modulated microscopy.
Torsion Modes
In contact mode AFM it is possible to monitor the
torsion motions of the cantilever as it is scanned across a surface.
Figure 9: Torsions of the cantilever are measured
in the AFM. Changes in the torsion of the cantilever are an
indication of changes in the surface chemical composition.
The amount of torsion of the cantilever is
controlled by changes in topography as well as changes in surface
chemical properties. If a surface is perfectly flat but has an
interface between two different materials, it is often possible to
image the change in material properties on a surface. This technique
is similar to lateral force microscopy (LFM).
