Jörg Flock

X-Ray Fluorescence Spectroscopy for Laboratory Applications


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E 0 maximum energy of the electrons

      If this process is carried out in an X-ray tube, the generated radiation must be directed at the sample through an exit window. The exit window of the tube absorbs the low-energy parts of the primary spectrum. This process is described by the following addition to Kramers' law, in which μ is the mass attenuation coefficient, ρ is the density, and d is the thickness of the tube window:

      (2.3)

      In addition to the continuous radiation, there are also line-like spectral components in the energy range of X-rays, which are generated by electron transitions in an atom. For this purpose, an internal electron level must be ionized by an energy input, which is higher than the binding energy of the electron. This excitation is possible by radiation, i.e. electron, proton, or even X-rays themselves or by the generation of a high-energy plasma. The resulting electron vacancy in an inner shell is filled by electrons of outer shells, in order to transfer the atom to a stable state again. These transitions can occur from different electron levels, resulting in a series of X-ray lines being emitted. The energy level differences depend on the type of the emitting atom; therefore, this radiation is called the characteristic radiation. The labeling of these lines starts with the designation of the primary vacancy, i.e. when the innermost K-shell is ionized it is K-radiation, when the L-shell is primarily ionized it is L-radiation, etc.

      The energies of the electron levels depend mainly on the number of protons of the atom, i.e. on the atomic number. This means that the energy differences depend on the type of the atoms. These energy differences are described by Moseley's law.

      with

E = energy difference between the electron levels
Z = atomic number of the atom
C1, C2 = constants

      2.2.2 Intensity of the Characteristic Radiation

Illustration depicting the labels of electron transitions with their corresponding line names and the approximate intensity ratios within a series as well as between the main lines of the different series.



K-series L-series M-series
100 Approx. 5–10 Approx. 1
1 K–L3 100 1 L3–M5 100 1 M5–N7 100
2 K–L2 50 1 L2–M4 50 2 M5–N6 100
1,2 K–L23 150 2