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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part BS. Istanbul 2004 
  
offers the possibility to bridge optical 3D measurement 
methods and scanning probe microscopy. For a better 
understanding, 3D measurement methods in micro-range are 
divided into surface und volumetric methods. An overview 
of important techniques is given in Table 1. The next two 
chapters will deal with an overview of relevant micro-range 
measurement methods. 
  
: Volumetric 
Surface measurement 
measurement 
methods 
methods 
  
Light Microscopy and 
or mechanical) shape from focus 
Micro-optical Confocal Laser 
triangulation methods | Scanning Microscopy 
(structured light) (CLSM) 
(Environmental) Transmission 
Scanning Electron Electron Microscopy 
Profilometry (optical 
  
  
  
Microscopy ([E] SEM) (TEM) and 
combined with tomographical 
photogrammetry methods 
Atomic Force Micro-Tomography 
Microscopy (AFM) (Micro CT) 
  
  
  
  
(Laser-) Interferometry 
  
Table 1. 3D micro-measurement methods 
2.2 Surface measurement 
Scanning Electron Microscope and Photogrammetry 
The electron microscope uses electrons instead of light for 
imaging. In scanning electron microscopy, the signal of a 
sample surface is generated by an accelerated electron beam 
that is scanned over a sample surface “line by line”. Thereby, 
electrons of the primary beam interact with the atoms of the 
surface. In elastic and inelastic scattering processes, 
electrons of a broad energy spectrum are emitted from the 
sample surface. Two different types of emitted electrons are 
commonly used for imaging: Secondary (SE) and 
Backscattered (BSE) electrons. SE are created in the sample 
itself and only capable to leave it, if generated in the first 
few nanometres. Therefore, SE carry the high-resolution 
information. SE emitted from the sample are detected by a 
photomultiplier system. The signal is then converted to a 
digital grey-scale image with an analogue-digital-adapter. 
What makes the SEM so valuable for micro-range 
measurements are the topographic details of the scanned 
images and the large depth of focus. Also, SEM provides a 
fairly high resolution due to the properties of the electron 
optical system. Although the wavelength of the electrons 
could be in the picometer range, due to lens aberration the 
aperture of the magnetic lenses of electron microscopes must 
not exceed values of about 10-2 rad (0.7 - 1.3 rad in light 
optics). This limitation results in a maximum resolution in 
the nanometer range. The depth of focus is also affected by 
the electron-probe aperture and is quite large in 
correspondence to the small aperture. The depth of focus of a 
SEM is at least 10 times the depth of focus of the LM. At 
high magnification it still is in the micrometer range. This 
fact had to be considered when planning size and shape of 
the calibration object. 
A specific feature of image acquisition with the SEM is the 
formation of very long focal length in combination with a 
virtual projection centre. Therefore, the image process is 
described with parallel geometry. Magnification and 
working distance, which is the distance between the electron 
emission pole and the specimen, have to remain constant 
during image acquisition for photogrammetric evaluation. 
Photogrammetric processing software has to take into 
account the special properties of SEM imaging described 
above. In order to increase the accuracy of 3D point 
determination, a bundle adjustment with should be applied 
[Maune 1976, Ghosh et al., 1976, El Ghazali 1984, Hemmleb 
2001]. At magnifications higher than 500, usually parallel 
projection equations are used. The bundle adjustment 
approach also offers the possibility for photogrammetric 
calibration of SEM. With the known calibration parameters 
of the SEM and defined rules for the image data acquisition, 
the photogrammetric processing of surface models requires 
mostly only two images. They have to be achieved by tilting 
the sample on a suitable working stage [Sinram et al, 
2002b]. 
The calibration of SEM includes at least the determination of 
the particular magnification (image scale) and the tilting 
angles. Depending on the chosen imaging model, the focal 
length has to be calculated too. Because of the necessity to 
rotate the sample in a fixed imaging system (like the SEM) 
the calibration data describe the motion of the working 
stage. The calibration of the SEM should be repeated from 
time to time, because the conditions of image acquisition do 
not remain constant in electron microscopy. 
Environmental Scanning Electron Microscope (ESEM) and 
Photogrammetry 
A special kind of scanning electron microscopy technique 
that operates at high pressures was introduced 1979 by 
Danilatos [Danilatos et al, 1979]. On the one hand, the 
technique allowed to look at liquid and hydrated samples 
and it simplified the preparation of the specimen. The 
approach was optimized by FEI Company (Eindhoven, 
Netherlands) and is offered under the name "environmental 
scanning electron microscope" (ESEM). The ESEM operates 
at pressures of 0.1 to about 20 Torr in its specimen chamber. 
The minimum pressure to keep water in the liquid phase at 
4°C is 6.1 Torr. A multiple pressure limiting aperture system 
(PLA) supplemented by a gaseous secondary electron (GSE) 
detector enables the ESEM to work under such conditions 
The PLA system allows a high water pressure in the specimen 
chamber without affecting the high vacuum at the top of the 
microscope column, where the electron source is located. It 
is not possible to use the regular SE detector in a gaseous 
environment. But, the GSE- detector takes advantage of the 
presence of gas in the specimen chamber where the SE scatter 
at the gas molecules present in the specimen chamber. One 
effect of the collision is the release of more SE from every 
collision, thereby provoking a cascade reaction with 
sufficient SE yield for the GSE detector. The ESEM is 
frequently used in material research, dental research and 
more and more in the field of life sciences. 
Atomic Force Microscopy 
Atomic Force Microscopy (AFM), also known as Scanning 
Force Microscopy (SFM) belongs to the methods of 
Scanning Probe Microscopy (SPM). The AFM measures 
atomic interactions between the sample surface and the 
probe head.