where K is a constant, p and Z are the density and the atomic number of the investigated material gia ©
and E is the energy of the incident photons. located In
This attenuation law explains the contrast observed in the x-ray radiograph of a bulky material Synchrotl0
because each point of a detector placed behind the sample is situated in front of a different path. If eles
the material is heterogeneous, the integral value of u(x,y,z) varies also with y and z. the elects”
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X-ray Tomography features (2
o Very
The drawback of radiography is that a high amount of information is projected on one single plane, py:
and the resulting image can be difficult to interpret if the number of microstructural features along depend
the thickness of the sample is important. Tomography overcomes this drawback by combining the SA OB
information of a high number of such radiographs, each being taken with a different orientation of fra
the sample in front of the detector. If the angular step between each radiograph is small enough, it is wii
possible from the complete set of radiographs, to recalculate the local value of u(x,y,z) in each point fo
of the sample. This reconstruction is performed thanks to an appropriate software based on the | N
filtered back-projection algorithm described for instance in (1). ER .
Different setups can be used. They all contain a source, a rotation stage on which the object is fixed, The D -
and a x-ray detector. The easiest way of getting digitized images is to use directly a two- (Des
dimensional radioscopic detector composed of a screen transforming the x-rays into visible light shel 2
which are then transferred by appropriate optic lenses to a cooled CCD camera (lines and rows of rsd
sensitive elements). The common geometric constraint of the different setups is that the axis of ~~ 5%
rotation of the sample must be parallel to the plane of the detector and its image must be aligned
with one of the colums of the CCD (preferably the central column). The crucial point in applying
tomography to materials science is the achievable spatial resolution. Its limit value is mainly
governed by the available photon flux at the level of the sample and by the setup as it will be
described in the two next sections. For medicine tomography (medical scanner) this limit resolution
if of the order of 300 pm. Materials scientists whishing to see and distinguish features with a size of
the order of 1 um had to develop appropriate tools.
Medium resolution microtomography
For a limit resolution of the order of 8 um (medium resolution), a cone beam system can be used
with a classical microfocus x-ray tube as the source. Such a device has been for instance assembled
in the CNDRI laboratory at INSA de Lyon. With this diverging geometry (see figure 1), the
magnification can be easily varied by changing the position of the sample in the space between the
source and the detector. The limit resolution is there due to the size of the micro-focus which
introduces blur in the projected image. This size has a minimum value because if the source size .
gets too small, the flux at the level of the sample becomes so low that the acquisition time required ! qi
to record a single radiograph is too long for a realistic analysis. In such a laboratory setup a © *
polychromatic source is used in order to keep the acquisition time acceptable. This may introduce (De
artefacts due to beam-hardening and does not allow to reconstruct quantitatively the absorption
coefficient u. Phase co
High resolution microtomography LES
Ia
We emphasized in the previous section that the setups using x-ray tubes are limited because of the Mere
flux delivered by this kind of source. The best quality images in terms of signal to noise ratio and Between
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