Upon ejection the kinetic energy of the Auger electron corresponds to the difference between energy of the initial electronic transition and the ionization energy for the shell from which the Auger electron was ejected. These energy levels depend on the type of atom and the chemical environment in which the atom was located. Thus by monitoring the energy of Auger electrons it is possible to determine the identity of the emitting atom and some information about its environment. This is [Auger electron spectroscopy]? |
Upon ejection the kinetic energy of the Auger electron corresponds to the difference between energy of the initial electronic transition and the ionization energy for the shell from which the Auger electron was ejected. These energy levels depend on the type of atom and the chemical environment in which the atom was located. [Auger electron spectroscopy]? stimulates the emission of Auger electrons by bombarding a sample with either X-rays or energetic electrons and measures the intensity of Auger electrons as a function of the Auger electron energy. The resulting spectra can be used to determine the identity of the emitting atoms and some information about their environment. |
Upon ejection the kinetic energy of the Auger electron corresponds to the difference between energy of the initial electronic transition and the ionization energy for the shell from which the Auger electron was ejected. These energy levels depend on the type of atom and the chemical environment in which the atom was located. [Auger electron spectroscopy]? stimulates the emission of Auger electrons by bombarding a sample with either X-rays or energetic electrons and measures the intensity of Auger electrons as a function of the Auger electron energy. The resulting spectra can be used to determine the identity of the emitting atoms and some information about their environment.