Jörg Flock

X-Ray Fluorescence Spectroscopy for Laboratory Applications


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a few tens of seconds to a few minutes. It should be noted that samples containing a percentage of oxidizable material (e.g. metals) can absorb oxygen due to the heating during grinding, whereby the composition of the sample material changes.

      3.4.2 Preparation by Pouring Loose Powder into a Sample Cup

      The following factors influence the analysis accuracy most:

       The film of the sample cup absorbs both the incident and the analyte radiation. This means that low-energy radiation of lighter elements in particular cannot or can only badly be detected. This can lead to significant analytical errors if the analyzed materials have a high content of light elements. In addition, it is possible that contaminations in the film of the sample cup counterfeit elements or their content in the sample.Figure 3.8 Dependence of fluorescence intensity on the morphology of the sample.Source: Courtesy of S. Hanning, FH Münster.

       The measurement often takes place in air, on the one hand, in order to save the time pumping down the sample chamber, but on the other hand also to avoid contamination of the spectrometer by swirling sample particles. Air in the beam path acts as an absorber. The contamination of the spectrometer during evacuation with sample particles can be avoided by covering the sample cup with a lid, see Figure 3.17.

       The relatively large surface roughness of loose samples influences the analytical accuracy for light elements. Different information depths of the fluorescence radiation result in their varying absorption.

       Owing to the filling process the sample density is not uniform. This significantly influences the reproducibility of the analytical result. This is illustrated in Figure 3.8, which shows the measured intensities of Pb in a loose powder of synthetic granules and correspondingly in a pressed pellet of the same material.

      It needs to be considered that in case of wavelength-dispersive spectrometry (WDS) instruments the film is thermally stressed by the high excitation intensity, i.e. long measurement times should be avoided.

      3.4.3 Preparation of the Measurement Sample by Pressing into a Pellet

Photograph of a press die model that is used to produce pellets from small-sized materials.

      Source: Courtesy of Specac Ltd.

       direct pressing of the ground raw material without any additives;

       mixing the sample with a binder and pressing the mixture into a pellet. The binder increases the strength and thus, if necessary, allows multiple use of the pellet. At the same time, a dilution of the matrix is achieved. The binders used are cellulose, wax, or other soft materials;

       pressing the sample material with a binder into solid sample holders such as rings or aluminum molds. The rings are made of steel or plastic. The material of the Al molds must have high purity in order to avoid superpositions of the sample spectrum with that of high-energy fluorescence radiation of impurities. This support of the sample material with molds is particularly useful for often used samples, where particles can flake off and contaminate the spectrometer. The pressing of small-particle material produces stable pellets with very smooth surfaces, as shown in Figure 3.10a;

       simultaneous pressing of the sample material into a substrate made of binder or boric acid utilized as a sample vessel. In this case, a test sample can also be produced with a small amount of sample material. Samples with a binder carrier pellet are shown in Figure 3.10b. Calibration samples can also be produced by this preparation method in order to ensure a high analytical accuracy even in the case of small sample quantities. However, an increased spectral background has to be expected for samples prepared in this way because the high-energy incident radiation is scattered on the light matrix of the sample mold;Figure 3.10 Pressed pellet (a) and cross section of a pressed pellet in binder (b).

       pressing the sample material at elevated temperatures. Particularly in the case of organic materials, this can lead to a gluing of the individual sample particles and thus to stable pellets; see for example in Section 10.13.2.