Abstract
Three most common methods of ionizing the actinides using thermal ionization are discussed. The first and most commonly used technique involves evaporating the oxide from a side filament and ionizing it on a hot rhenium center filament. The second method, which is used almost as frequently as the first, involves loading the sample onto a rhenium single filament and reducing the sample. This method gives excellent sensitivity for small samples using a multiplier as the detector, but is less suitable for large samples and Faraday cup detectors. The first method is well suited for large samples on instruments with Faraday cup detectors. The third technique involves loading the sample onto a single tantalum filament, flashing to red heat in the air, and analyzing the oxide or dioxide ion beam. This technique gives reasonably stable ion beams for the lighter actinides and all of the lanthanides. It is not as sensitive as the other methods and is mentioned mainly for historical interest as it was widely used 25 years ago. The suitability of these methods for thorium, uranium, plutonium and americium, as well as for the lanthanides and other fission product elements are covered in detail. Besides these three methods, the
More>>
Citation Formats
Delmore, J. E.
Ionization of selected elements of interest in the nuclear fuel cycle.
Netherlands: N. p.,
1978.
Web.
Delmore, J. E.
Ionization of selected elements of interest in the nuclear fuel cycle.
Netherlands.
Delmore, J. E.
1978.
"Ionization of selected elements of interest in the nuclear fuel cycle."
Netherlands.
@misc{etde_8489436,
title = {Ionization of selected elements of interest in the nuclear fuel cycle}
author = {Delmore, J. E.}
abstractNote = {Three most common methods of ionizing the actinides using thermal ionization are discussed. The first and most commonly used technique involves evaporating the oxide from a side filament and ionizing it on a hot rhenium center filament. The second method, which is used almost as frequently as the first, involves loading the sample onto a rhenium single filament and reducing the sample. This method gives excellent sensitivity for small samples using a multiplier as the detector, but is less suitable for large samples and Faraday cup detectors. The first method is well suited for large samples on instruments with Faraday cup detectors. The third technique involves loading the sample onto a single tantalum filament, flashing to red heat in the air, and analyzing the oxide or dioxide ion beam. This technique gives reasonably stable ion beams for the lighter actinides and all of the lanthanides. It is not as sensitive as the other methods and is mentioned mainly for historical interest as it was widely used 25 years ago. The suitability of these methods for thorium, uranium, plutonium and americium, as well as for the lanthanides and other fission product elements are covered in detail. Besides these three methods, the resin bead technique and the silica gel technique are mentioned. The conclusion is that there is a great deal of work which needs to be carried out before a complete understanding of these ionization processes are understood.}
place = {Netherlands}
year = {1978}
month = {Jul}
}
title = {Ionization of selected elements of interest in the nuclear fuel cycle}
author = {Delmore, J. E.}
abstractNote = {Three most common methods of ionizing the actinides using thermal ionization are discussed. The first and most commonly used technique involves evaporating the oxide from a side filament and ionizing it on a hot rhenium center filament. The second method, which is used almost as frequently as the first, involves loading the sample onto a rhenium single filament and reducing the sample. This method gives excellent sensitivity for small samples using a multiplier as the detector, but is less suitable for large samples and Faraday cup detectors. The first method is well suited for large samples on instruments with Faraday cup detectors. The third technique involves loading the sample onto a single tantalum filament, flashing to red heat in the air, and analyzing the oxide or dioxide ion beam. This technique gives reasonably stable ion beams for the lighter actinides and all of the lanthanides. It is not as sensitive as the other methods and is mentioned mainly for historical interest as it was widely used 25 years ago. The suitability of these methods for thorium, uranium, plutonium and americium, as well as for the lanthanides and other fission product elements are covered in detail. Besides these three methods, the resin bead technique and the silica gel technique are mentioned. The conclusion is that there is a great deal of work which needs to be carried out before a complete understanding of these ionization processes are understood.}
place = {Netherlands}
year = {1978}
month = {Jul}
}