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Nuclear Properties, Availability, and Applications

Selected nuclear properties of the principal isotopes of berkelium are listed in Table I (6). In addition to these isotopes, ranging from mass numbers 240 to 251, there are spontaneously fissioning isomers known for berkelium mass numbers 242, 243, 244, and 245, all with half-lives of less than 1 /usee. Only 249Bk is available in bulk quantities for chemical studies, as a result of prolonged neutron irradiation of Pu, Am, or Cm (7). About 0.66 g of this isotope has been isolated from [Pg.30]

Mass Decay Decay Ground-state production [Pg.31]

Besides the research use of 249Bk for the characterization of the chemical and physical properties of element 97, its relatively rapid decay to 249Cf (0.2% per day) makes it a valuable source of this important isotope of californium for chemical study. This genetic relationship has been exploited in studies of the chemical consequences of beta (fi) decay in the bulk-phase solid state (12, 13). [Pg.31]

There have been no reports of practical applications for any of the isotopes of berkelium. [Pg.31]

Summary of the Nuclear Properties, Availability, and Applications of Selected Plutonium Isotopes... [Pg.452]

Its importance depends on the nuclear property of being readily fissionable with neutrons and its availability in quantity. The world s nuclear-power reactors are now producing about 20,000 kg of plutonium/yr. By 1982 it was estimated that about 300,000 kg had accumulated. The various nuclear applications of plutonium are well known. 238Pu has been used in the Apollo lunar missions to power seismic and other equipment on the lunar surface. As with neptunium and uranium, plutonium metal can be prepared by reduction of the trifluoride with alkaline-earth metals. [Pg.205]

The suitability of a radionuclide for a particular medical application will depend upon its availability in a radiochemically pure form, its nuclear properties and its chemical properties. In respect of the first of these considerations it is necessary to eliminate any extraneous radiation sources from a material destined for medical use. This need for very high radiochemical purity has a bearing on the means by which the radionuclide is produced. One potential method is by nuclear fission of a heavy element. This approach has the advant e that carrier free radioisotopes of high specific activity may be produced. However, because the process produces a complex mixture of FPs, painstaking separation and purification of the desired radionuclide will be necessary. The problem is simplified somewhat by using a pure target isotope to produce an FP which has rather unique properties. Thus fission produces which may be separated from the other FPs by virtue of its volatility. Fission in pure may also be used to prepare Mo in carrier free form, although contamination by Ru, I and Te was a problem in early... [Pg.964]

In 1965, Richards and his collaborators at Brookhaven National Laboratories (N.Y.) have introduced the Mo/ Tc generator for clinical application (Richards 1966). This radionuclide system made technetium-99m available for clinical research and has stimulated the development of the first labeled compounds, which had a considerable impact on radiochemistry and nuclear medicine (Andros et al. 1965 Harper et al. 1966 McAfee et al. 1964a, b Stern et al. 1965, 1966). In the years to follow, diagnostic nuclear medicine procedures based on " Tc pharmaceuticals increased to approximately 85%. The reasons for this rapid growth were the ideal nuclear properties of techne-tium-99m, its availability worldwide as a radionuclide generator system, and the development of new labeling techniques. [Pg.7]

The use of the actinide elements fall into three categories (i) for imderstanding fundamental chemistry and the nature of the periodic system, (ii) as products, in the large scale use of nuclear energy, and (iii) miscellaneous applications, where the particular physical, chemical or nuclear properties are valuable. Only the last aspect is discussed here, the others are treated elsewhere in this book. The availability of transuranium element isotopes suitable for experiments is listed in Table 16.4. [Pg.436]

Sapphire is produced commercially throughout the world and is used in virtually every industry. The optical, electrical, chemical, mechanical, and nuclear properties of sapphire fibers, as described in the literature [13], make them an ideal material for many applications other than their use as sensor or reinforcing fibers for metal and ceramic matrix composites. Frequently, the combination of two or more of its properties make sapphire the only material available to solve complex engineering design problems. [Pg.114]

See other pages where Nuclear Properties, Availability, and Applications is mentioned: [Pg.29]    [Pg.30]    [Pg.117]    [Pg.29]    [Pg.30]    [Pg.117]    [Pg.1262]    [Pg.126]    [Pg.884]    [Pg.886]    [Pg.212]    [Pg.128]    [Pg.144]    [Pg.1319]    [Pg.1597]    [Pg.964]    [Pg.965]    [Pg.235]    [Pg.85]    [Pg.108]    [Pg.17]    [Pg.965]    [Pg.75]    [Pg.17]    [Pg.1262]    [Pg.124]    [Pg.664]    [Pg.677]    [Pg.656]    [Pg.669]    [Pg.440]    [Pg.599]    [Pg.7109]    [Pg.7110]    [Pg.125]    [Pg.168]    [Pg.57]    [Pg.706]    [Pg.709]    [Pg.719]    [Pg.73]    [Pg.366]    [Pg.365]    [Pg.73]    [Pg.2]   


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Applications and properties

Nuclear properties

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