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blanking and unblanking the beam at specific lateral 
coordinates (Figure 2). Repetitive scanning of the ion beam 
in presence of the gas then results in the construction of a 
multilayer metal film of determined height and form, in our 
case the slope step pyramidal structures. 
FI3 DEPOSITION HIB MILLING 
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Figure 2. Schematic drawing of the two patterning modes of 
focused ion beam (FIB) systems. In the left drawing, the 
process of milling is shown. In the right drawing, the 
process of deposition is shown. The deposition product is a 
layer of metal, usually tungsten (W) or platinum (Pt). The 
metal is introduced into the specimen chamber as an 
organometallic compound. It is applied very close to the 
sample surface through a valve needle with a very fine tip. If 
hit by the ion beam or the secondary electrons generated by 
the beam at the sample surface, the organometallic gas 
decomposes, whereby the metal deposits at the sample 
surface. 
3.2 Design and specification 
The development and design of the calibration object was 
determined by the various demands of the particular 
measurement methods (Figure 3). 
    
t— 1 um — 
Figure 3. SEM image of a calibration pyramid made with the 
technique of gas assisted FIB. The pyramidal shaped 
calibration object with slope steps approximately measures 
6pm in width and length and 3pm in height. It can be used 
for SEM calibration at magnifications of 8000x to approx. 
20000x. The calibration object has up to 38 nanomarkers as 
control points. They were applied using FIB milling. The 
distribution of the nanomarkers is non-symmetrical, so they 
can always be clearly identified and associated. 
Also, the peculiarities of the calibration process itself had to 
be taken into consideration. In general, it is an advantage in 
3D measurement methods, if the calibration object covers 
the measurement volume. This is especially important in 3D 
measurements with SEM, because the positioning of the 
calibration object is restricted by the properties of the 
sample and the tilting stage. 
Nanomarkers [Hemmleb et al., 1995, Sinram et al., 2002b] on 
the calibration object serve as control points carrying the 
spatial information. They must be easy to detect as discrete 
points in both, the scanning electron microscope and the 
atomic force microscope. The distribution on the lower level 
is non-symmetrical, in order to be always informed of the 
pyramid’s orientation. The control points are detected via 
semi-automated image processing methods. Therefore, their 
coordinates can be directly used for the photogrammetric 
bundle block adjustment. The cascade pyramidal shape of 
the calibration structure allows the usage at a range of 
magnifications. Together with the sloping edges, it is 
guaranteed that the control points on a lower level maintain 
visible, even if tilted in the SEM for the calibration process. 
Additionally, the angle of the pyramidal cascade step slopes, 
in respect to the surface plane was designed to be smaller 
than the aperture angle of the AFM tip. 
We wanted to be able to calibrate the SEM at a maximum 
range of magnification. Therefore, the measures had to 
represent a structure that is still completely within the range 
of the depth of focus, when filling the field of view of an 
SEM image. Most AFM scanners can handle a scan area up to 
100um with a maximum structure elevation of about Sum. 
Therefore the size of the calibration structure was limited by 
the specifications of the AFM scanner and the optical 
limitations of the SEM. 
3.3 Application for correlative measurements 
non-symmetrical nanomarker 
  
  
  
  
  
  
  
  
  
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Figure 4. Contour plot of the calibration object measured by 
atomic force microscopy at the PTB (Phsikalisch-technische 
Bundesanstalt, Braunschweig). Nanomarkers are nfarked as 
numbers 1 to 37. The arrow shows the symmetry breaking 
nanomarker. 
Figure 3 and Figure 4 show the functionality of the design 
of the 3D pyramidal calibration object, because the 
nanomarkers can be clearly identified in both measurement