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The analysis method known as auger electron spectroscopy is frequently used in the field of materials science and, more specifically, in the study of surfaces.
It is a type of electron spectroscopy that uses the Auger effect and is based on the examination of energetic electrons released from an excited atom following a sequence of internal relaxation events.
The inter- and intrastate transitions of electrons in an excited atom produce the Auger effect, an electronic phenomenon at the core of AES.
A core state electron may be lost, leaving a hole, when an atom is probed by an outside force, such as a photon or a stream of electrons with energies between several eV and 50 keV.
The Global Auger Electron Spectroscopy (AES) Market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
Markets for material sciences, metallurgy, gas phase chemistry, and other applications make up the auger electron spectroscopy (AES) industry.
The development of advanced materials and chemicals for a broad range of applications is anticipated to result in a high CAGR for the demand for AES.
Materials science is the study of the properties and traits of various types of materials, including ceramics, metals, semiconductors, plastics, and composites.
Over the next few years, it is anticipated that market demand will be boosted by funding obtained from both public and private sources in the area of research and development.
Among other things, cross section analysis, particle analysis, identifying defects and the thickness of the oxide layer in electronic devices, and auger electron spectroscopy are some of its uses.
Additionally, insulating materials, semi-conductive masses, and conductors are all analysed using AES. The Auger spectroscopes, also referred to as scanning Auger microscopes, are used to create a significant number of electron microscopes. (SAMs).
These microscopes can create chemical images that are spatially resolved and of great precision. When released, an Auger electron has a very specific quantity of momentum and kinetic energy.
To learn more about the elemental configuration of the surface and to create an image of it, an exact analysis of the energy carried by the electrons is necessary.
