Principle and Features of X-ray Fluorescence Spectrometry








 Principle of Fluorescent X-ray Generation  EDX-8100 Instrument Construction
                                                                         Sample
 When a sample is irradiated with X-rays from an X-ray tube, the
 atoms in the sample generate unique X-rays that are emitted from   X-ray
 ̠Ћ
 the sample. Such X-rays are known as "fluorescent X-rays" and
 they have a unique wavelength and energy that is characteristic of
 each element that generates them. Consequently, qualitative   K
 analysis can be performed by investigating the wavelengths of the
                                Collimator
 X-rays. As the fluorescent X-ray intensity is a function of the   L
 concentration, quantitative analysis is also possible by measuring   K shell  Sample
 ̠Ќ                                                                     observation
 X-ray
 the amount of X-rays at the wavelength specific to each element.  ʢЕ=Е 0ʣ  camera
 L shell  M                  Primary filter
 LЋ
 M shell
 Atomic nucleus  Electron  Hole
 Electron Paths and Principle of X-ray Generation Expressed as a Bohr Model


 Supports Various Applications in Many Fields

                                                                                          Detector
 Electrical/electronic materials  Ceramics
 ɾRoHS and halogen screening  ɾAnalysis of ceramics, cement, glass, bricks, and clay
 ɾThin-film analysis for semiconductors, discs, liquid crystals, and
    solar cells  Oil and petrochemicals
 ɾAnalysis of sulfur in oil                 X-ray tube
 Automobiles and machinery
 ɾAnalysis of additive elements and mixed elements in lubricating oil
 ɾELV hazardous element screening
 ɾComposition analysis, plating thickness measurement, and chemical  Chemicals
    conversion coating film weight measurement for machine parts  ɾAnalysis of products and organic/inorganic raw materials
 ɾAnalysis of catalysts, pigments, paints, rubber, and plastics
 Ferrous/non-ferrous metals
 ɾMain component analysis and impurity analysis of raw materials,  Environment
    alloys, solder, and precious metals
 ɾAnalysis of soil, effluent, combustion ash, filters, and fine
 ɾComposition analysis of slag
    particulate matter
 Mining  Pharmaceuticals
 ɾGrade analysis for mineral processing
 ɾAnalysis of residual catalyst during synthesis
 ɾAnalysis of impurities and foreign matter in active pharmaceutical
    ingredients
 Agriculture and foods

 ɾAnalysis of soil, fertilizer, and plants
 ɾAnalysis of raw ingredients, control of added elements, and
    analysis of foreign matter in foods
 Other

 ɾComposition analysis of archeological samples and precious stones,
    analysis of toxic heavy metals in toys and everyday goods



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