Abstract
In the third-generation synchrotron radiation sources represented by the SPring-8, the synchrotron radiation is generated mainly by undulators rather than the bending magnets. Fundamental compositions of the undulator are a permanent magnet array, a driver for adjusting the magnet gap to vary the magnetic field strength and a vacuum chamber. The most important technology to realize high performance undulators is the vacuum technology. Attention is needed especially for the undulator of in-vacuum type since the magnet array is inside the vacuum chamber which is a part of the vacuum system of the storage ring. The undulator should be provided with a mechanical accuracy as a synchrotron radiation generator and also a reliability as a part of the vacuum system. Necessary technologies for preparing an undulator of in-vacuum type with a short magnet-periodicity and a narrow magnet-gap is described. (author)
Kitamura, Hideo
[1]
- RIKEN, Harima Institute, Mikazuki, Hyogo (Japan)
Citation Formats
Kitamura, Hideo.
Vacuum technology in synchrotron radiation sources.
Japan: N. p.,
2005.
Web.
doi:10.3131/jvsj.48.97.
Kitamura, Hideo.
Vacuum technology in synchrotron radiation sources.
Japan.
https://doi.org/10.3131/jvsj.48.97
Kitamura, Hideo.
2005.
"Vacuum technology in synchrotron radiation sources."
Japan.
https://doi.org/10.3131/jvsj.48.97.
@misc{etde_20620479,
title = {Vacuum technology in synchrotron radiation sources}
author = {Kitamura, Hideo}
abstractNote = {In the third-generation synchrotron radiation sources represented by the SPring-8, the synchrotron radiation is generated mainly by undulators rather than the bending magnets. Fundamental compositions of the undulator are a permanent magnet array, a driver for adjusting the magnet gap to vary the magnetic field strength and a vacuum chamber. The most important technology to realize high performance undulators is the vacuum technology. Attention is needed especially for the undulator of in-vacuum type since the magnet array is inside the vacuum chamber which is a part of the vacuum system of the storage ring. The undulator should be provided with a mechanical accuracy as a synchrotron radiation generator and also a reliability as a part of the vacuum system. Necessary technologies for preparing an undulator of in-vacuum type with a short magnet-periodicity and a narrow magnet-gap is described. (author)}
doi = {10.3131/jvsj.48.97}
journal = []
issue = {3}
volume = {48}
journal type = {AC}
place = {Japan}
year = {2005}
month = {Mar}
}
title = {Vacuum technology in synchrotron radiation sources}
author = {Kitamura, Hideo}
abstractNote = {In the third-generation synchrotron radiation sources represented by the SPring-8, the synchrotron radiation is generated mainly by undulators rather than the bending magnets. Fundamental compositions of the undulator are a permanent magnet array, a driver for adjusting the magnet gap to vary the magnetic field strength and a vacuum chamber. The most important technology to realize high performance undulators is the vacuum technology. Attention is needed especially for the undulator of in-vacuum type since the magnet array is inside the vacuum chamber which is a part of the vacuum system of the storage ring. The undulator should be provided with a mechanical accuracy as a synchrotron radiation generator and also a reliability as a part of the vacuum system. Necessary technologies for preparing an undulator of in-vacuum type with a short magnet-periodicity and a narrow magnet-gap is described. (author)}
doi = {10.3131/jvsj.48.97}
journal = []
issue = {3}
volume = {48}
journal type = {AC}
place = {Japan}
year = {2005}
month = {Mar}
}