Undulator: Difference between revisions

Latest revision as of 03:35, 13 February 2025

A device used in synchrotron radiation sources and free-electron lasers

Overview[edit]

An undulator is a periodic structure of magnets used in synchrotron radiation sources and free-electron lasers (FELs) to produce highly collimated and intense beams of electromagnetic radiation. The undulator forces a beam of electrons to undergo a series of oscillations, which results in the emission of radiation due to the synchrotron effect.

Principle of Operation[edit]

Diagram of an undulator showing the periodic magnetic structure.

The undulator consists of a series of alternating magnetic fields, typically created by an array of permanent magnets or electromagnets. As the electron beam passes through these fields, it is deflected back and forth in a sinusoidal path. This oscillatory motion causes the electrons to emit radiation at specific wavelengths, determined by the period of the magnetic structure and the energy of the electrons.

The emitted radiation is coherent and can be tuned by adjusting the magnetic field strength or the energy of the electron beam. This tunability makes undulators essential components in modern synchrotron light sources and FELs, where precise control over the wavelength of the emitted light is required.

Applications[edit]

Undulators are used in a variety of applications, including:

Synchrotron light sources: Undulators are key components in synchrotron facilities, providing intense beams of X-rays for X-ray crystallography, spectroscopy, and other scientific research.
Free-electron lasers: In FELs, undulators are used to generate coherent laser light across a wide range of wavelengths, from the infrared to the X-ray region.
Medical imaging and therapy: The high-intensity X-rays produced by undulators are used in advanced imaging techniques and radiation therapy.

Comparison with Wigglers[edit]

Undulators are often compared to wigglers, another type of insertion device used in synchrotron radiation facilities. While both devices use periodic magnetic fields to produce radiation, undulators have a smaller magnetic field strength and a shorter period, resulting in narrower bandwidth and higher brightness of the emitted radiation. Wigglers, on the other hand, produce a broader spectrum of radiation with higher intensity but lower coherence.

Related pages[edit]

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-Undulator
+{{short description|A device used in synchrotron radiation sources and free-electron lasers}}
-An undulator is a device used in particle accelerators and synchrotron radiation sources to generate intense beams of electromagnetic radiation. It consists of a series of alternating magnetic poles and gaps through which charged particles, such as electrons, are accelerated. The alternating magnetic field causes the particles to oscillate, resulting in the emission of synchrotron radiation.
+==Overview==
+An '''undulator''' is a periodic structure of magnets used in [[synchrotron radiation]] sources and [[free-electron laser]]s (FELs) to produce highly collimated and intense beams of [[electromagnetic radiation]]. The undulator forces a beam of [[electrons]] to undergo a series of oscillations, which results in the emission of radiation due to the [[synchrotron radiation|synchrotron effect]].
-== History ==
+==Principle of Operation==
-The concept of the undulator was first proposed by Hans Motz and Albert W. Overhauser in 1945. However, it was not until the 1970s that practical undulators were developed and used in particle accelerators. Today, undulators are an essential component of many synchrotron radiation facilities around the world.
+[[File:Undulator.png|thumb|right|Diagram of an undulator showing the periodic magnetic structure.]]
+The undulator consists of a series of alternating [[magnetic field]]s, typically created by an array of permanent magnets or electromagnets. As the electron beam passes through these fields, it is deflected back and forth in a sinusoidal path. This oscillatory motion causes the electrons to emit radiation at specific wavelengths, determined by the period of the magnetic structure and the energy of the electrons.
-== Operation ==
+The emitted radiation is coherent and can be tuned by adjusting the magnetic field strength or the energy of the electron beam. This tunability makes undulators essential components in modern synchrotron light sources and FELs, where precise control over the wavelength of the emitted light is required.
-Undulators work based on the principle of magnetic resonance. When charged particles pass through the alternating magnetic field of the undulator, they experience a force that causes them to oscillate. As a result, they emit synchrotron radiation, which is a form of electromagnetic radiation that covers a wide range of wavelengths, from X-rays to infrared.
-== Applications ==
+==Applications==
-Undulators have a wide range of applications in various scientific fields. In particle accelerators, they are used to generate intense beams of synchrotron radiation for experiments in physics, chemistry, biology, and materials science. Synchrotron radiation produced by undulators is also used in medical imaging, industrial inspection, and materials characterization.
+Undulators are used in a variety of applications, including:
-== Advantages ==
+* '''Synchrotron light sources''': Undulators are key components in synchrotron facilities, providing intense beams of X-rays for [[X-ray crystallography]], [[spectroscopy]], and other scientific research.
-One of the main advantages of undulators is their ability to produce highly collimated and tunable beams of synchrotron radiation. The intensity and energy of the radiation can be controlled by adjusting the strength and spacing of the magnetic poles. This flexibility allows researchers to tailor the radiation to their specific experimental needs.
+* '''Free-electron lasers''': In FELs, undulators are used to generate coherent laser light across a wide range of wavelengths, from the infrared to the X-ray region.
+* '''Medical imaging and therapy''': The high-intensity X-rays produced by undulators are used in advanced imaging techniques and radiation therapy.
-== Limitations ==
+==Comparison with Wigglers==
-While undulators offer many advantages, they also have some limitations. One limitation is the requirement for high-energy particle beams to generate synchrotron radiation. This means that undulators are typically used in large-scale facilities that house particle accelerators. Additionally, the production of synchrotron radiation requires a significant amount of energy, making it an expensive process.
+Undulators are often compared to [[wiggler]]s, another type of insertion device used in synchrotron radiation facilities. While both devices use periodic magnetic fields to produce radiation, undulators have a smaller magnetic field strength and a shorter period, resulting in narrower bandwidth and higher brightness of the emitted radiation. Wigglers, on the other hand, produce a broader spectrum of radiation with higher intensity but lower coherence.
-== See also ==
+==Related pages==
 * [[Synchrotron radiation]]
-* [[Particle accelerator]]
+* [[Free-electron laser]]
-* [[Synchrotron radiation facility]]
+* [[Wiggler]]
+* [[Magnetic field]]
-== References ==
+* [[Electron beam]]
-<references />
-== External links ==
-* [https://example.com Example.com] - A website with more information on undulators.
 [[Category:Particle accelerators]]
 [[Category:Synchrotron radiation]]
-[[Category:Electromagnetic radiation]]
+[[Category:Free-electron lasers]]
-[[Category:Scientific instruments]]