X-Ray Fluorescence Spectroscopy for Laboratory Applications. Jörg Flock. Читать онлайн. Newlib. NEWLIB.NET

Автор: Jörg Flock
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Химия
Год издания: 0
isbn: 9783527816620
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instruments are sorting of scrap, the determination of toxic elements in consumer products, the tracking of ores in mining explorations, or the investigation of art objects. Equipment is offered by companies such as Thermo, Bruker, Hitachi, Olympus, or Spectro; these companies usually also carry ED X-ray spectrometers in their portfolio. They all work with comparable components and the performance achieved in the meantime is remarkable as well as comparable for all companies. The available computing technology on the instruments is limited by the battery power supply but allows for quantification of predefined material classes by means of standard-based calibrations. The analytical accuracy however is mainly limited due to the lack of sample preparation, and due to sample contaminations on site. In special cases, the transfer of measurement data to an external computer is possible, on which more powerful evaluation algorithms and procedures for data management are available.

      All these assemblies are now used in modern X-ray spectrometers. A more detailed description and compilation of the most important instrument classes is given in Section 4.3.

      2.4.1 Analysis Method

      In order to carry out an analysis various steps have to be taken starting with asking the right analytical questions – this applies not only to X-ray spectrometry.

      In the following discussions, unless otherwise stated, it is assumed that the sampling has already taken place and the material to be analyzed is available; this means that sampling here is not a part of the analysis. The sample material available in the laboratory is called laboratory sample (see DIN-51418-1 2008, Part 2, DIN-51418-2 2014).

      For carrying out an analysis it is required to determine the analytical strategy and the analytical method to be used. It is based on the material to be analyzed as well as the analytical task requested, specifically the definition of the elements to be analyzed, the estimation of the concentration range to be detected, and the desired uncertainties. Of course, one must take into account the available equipment and the required time. Therefore the following steps are necessary:

       Determination of the type of sample preparation, namely, manufacturing of the measurement specimen from the laboratory sample, taking into account the analytical taskthe parameters that have to be determined with the analysisthe time available for the entire analysis, including preparation, measurement, and data evaluationthe required analytical accuracy

       Definition of analysis conditions (e.g. excitation parameters and measurement time) and of the quantification model to be used

       Carrying out the measurements on the sample as well as, if necessary, on reference or monitor samples

       Qualitative and quantitative evaluation of results

       Estimation of measurement uncertainties

       Preparation of a report of the analytical results

      In the case of unknown samples and high accuracy requirements this process can take up a considerable amount of time; in the case of repetitive measurements on known sample material it is possible to obtain an analysis result in a very short time even with low measurement uncertainties.

      The individual steps can be summarized as follows:

       The actual measurement includes the determination of the test conditions as well as the measurement of the test sample itself and, if necessary, of the calibration samples with the available analytical technique.Figure 2.11 Steps for an analytical procedure.

       The analytical method includes the measurement, sample preparation, and evaluation of the measured data. The analytical method can be used in an identical way for comparable analytical questions.

       The analytical procedure includes additionally the sampling procedure and the data processing, namely, the preparation of the analysis report including a possible statistical evaluation of the results.

      When performing the measurement itself, the selection of the optimal measuring conditions as well as the processing and evaluation of the spectra, including quantification, is important. Finally, the estimation of the analysis errors and the uncertainties is an important part of an analysis procedure in order to assess the quality of the results. These considerations essentially depend on the respective analytical task.

      2.4.2 Sequence of an Analysis

      The first step in an analysis is to define its goal. Several separate problems have to be considered.

      2.4.2.1 Quality of the Sample Material

      The laboratory sample, i.e. the sample material that is available in the laboratory, can have different forms: it can be compact, it can be small-particle size granule or powder-like, or it can be a paste or even a liquid. Increasingly, finished products have to be analyzed for quality assurance or fault identification purposes. As far as possible, they should not be modified for the analysis. Knowing the sample material, important information about the sample matrix can be obtained for the evaluation, such as information about non-measurable light elements.

      2.4.2.2 Sample Preparation

      For the various material qualities, the possibility of different sample preparation techniques is required. They also depend on the type of the spectrometer as well as on the desired analytical accuracy.

      These options are discussed in detail in Chapter 3.

      2.4.2.3 Analysis Task

      Analytical tasks for element analyses can vary broadly. They can be

       a simple determination of the elements present in the laboratory sample (qualitative analysis);

       a monitoring of the content of one or more elements with respect to a predetermined threshold value (semiquantitative analysis);

       a comparison of the measured intensities of one or several elements with those of reference samples for identifying a material class (positive material identification – PMI);

       the quantitative determination of the mass fractions of some or all elements in the sample material with a predetermined uncertainty level as an overview analysis, as well as