Atomic force microscope (AFM)

Atomic force microscope (AFM)

The atomic force microscope measures the asperity of a sample using the atomic forces between the tip and the sample. To perform measurement, the user moves the cantilever, equipped with a sharp tip (probe) at its end, into proximity of a sample surface to a distance of several nanometers. In order to maintain a constant force between the tip and the sample (a constant deflection of the cantilever), the atomic force microscope gives feedback to the piezo scanner while scanning.
The displacement provided as feedback to the piezo scanner is measured to obtain the z-axial displacement, which is the surface structure.

A common way of measuring the displacement of the piezo scanner is the adoption of the optical lever method in which a laser beam is emitted on the back side of the cantilever and the reflected beam is detected by four-segment (or two-segment) photodiodes.

Advantages	Disadvantages
- High resolution (resolution: minimum distance between resolvable points) - Capable of 3D measurement with super-high magnification. Collected data can be processed. - Observation in atmospheric conditions is possible, not needing pretreatment of sample - Capable of analysing physical properties (electrical property, magnetic property, friction, viscoelasticity, etc.)	- Incapable of low magnification (wide range) measurement. Samples with significant asperity (level difference greater than a few μm) cannot be measured. - Difficulties in positioning due to the need to narrow down the field of view Analysis for each sample takes time - Inability to measure large samples due to the need for pretreatment and processing - Relatively difficult operations; Experience required for cantilever replacement, etc.

Advantages

Disadvantages

- High resolution (resolution: minimum distance between resolvable points)
- Capable of 3D measurement with super-high magnification. Collected data can be processed.
- Observation in atmospheric conditions is possible, not needing pretreatment of sample
- Capable of analysing physical properties (electrical property, magnetic property, friction, viscoelasticity, etc.)

- Incapable of low magnification (wide range) measurement. Samples with significant asperity (level difference greater than a few μm) cannot be measured.
- Difficulties in positioning due to the need to narrow down the field of view Analysis for each sample takes time
- Inability to measure large samples due to the need for pretreatment and processing
- Relatively difficult operations; Experience required for cantilever replacement, etc.

Very small measurable range

The atomic force microscope (AFM) is a magnifying observation equipment capable of measuring 3D textures of a minuscule area. Unlike scanning electron microscopes, it can acquire height data in numeric values, which enable quantification of sample and data post-processing. The AFM also allows for measurements in normal atmospheric conditions and is free from restrictions such as the need for sample pretreatment and electrical conductivity. On the other hand, however, it is subject to the limitation of narrow measuring range (XYZ) due to its high resolution capabilities. The AFM also suffer the difficulties of accurately positioning the probe to the measurement area and the need for knowledgeable operation (correct mounting of the cantilever, etc.)

"Instruments used for roughness measurements" page list