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ASTM C799-99(2005)
Standard Test Methods for Chemical, Mass Spectrometric, Spectrochemical, Nuclear, and Radiochemical Analysis of Nuclear-Grade Uranyl Nitrate Solutions
Standard Test Methods for Chemical, Mass Spectrometric, Spectrochemical, Nuclear, and Radiochemical Analysis of Nuclear-Grade Uranyl Nitrate Solutions
C0799-99R05
ASTM|C0799-99R05|en-US
Standard Test Methods for Chemical, Mass Spectrometric, Spectrochemical, Nuclear, and Radiochemical Analysis of Nuclear-Grade Uranyl Nitrate Solutions
Standard
C799 Standard Test Methods for Chemical, Mass Spectrometric, Spectrochemical, Nuclear, and Radiochemical Analysis of Nuclear-Grade Uranyl Nitrate Solutions>
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Significance and Use
Uranyl nitrate solution is used as a feed material for conversion to the hexafluoride as well as for direct conversion to the oxide. In order to be suitable for this purpose, the material must meet certain criteria for uranium content, isotopic composition, acidity, radioactivity, and impurity content. These methods are designed to show whether a given material meets the specifications for these items described in Specification C 788
3.1.1 An assay is performed to determine whether the material has the specified uranium content.
3.1.2 Determination of the isotopic content of the uranium is made to establish whether the effective fissile content is in accordance with the purchaser’specifications.
3.1.3 Acidity, organic content, and alpha, beta, and gamma activity are measured to establish that they do not exceed their maximum limits.
3.1.4 Impurity content is determined to ensure that the maximum concentration limit of certain impurity elements is not exceeded. Impurity concentrations are also required for calculation of the equivalent boron content (EBC), and the total equivalent boron content (TEBC).
Scope
1.1 These test methods cover procedures for the chemical, mass spectrometric, spectrochemical, nuclear, and radiochemical analysis of nuclear-grade uranyl nitrate solution to determine compliance with specifications.
1.2 The analytical procedures appear in the following order:
| Sections | |
| Determination of Uranium | 7 |
| Specific Gravity by Pycnometry | 15-20 |
| Free Acid by Oxalate Complexation | 21-27 |
| Determination of Thorium | 28 |
| Determination of Chromium | 29 |
| Determination of Molybdenum | 30 |
| Halogens Separation by Steam Distillation | 31-35 |
| Fluoride by Specific Ion Electrode | 36-42 |
| Halogen Distillate Analysis: Chloride, Bromide, and Iodide by Amperometric Microtitrimetry | 43 |
| Determination of Chloride and Bromide | 44 |
| Determination of Sulfur by X-Ray Fluorescence | 45 |
| Sulfate Sulfur by (Photometric) Turbidimetry | 46 |
| Phosphorus by the Molybdenum Blue (Photometric) Method | 54-61 |
| Silicon by the Molybdenum Blue (Photometric) Method | 62-69 |
| Carbon by Persulfate Oxidation-Acid Titrimetry | 70 |
| Conversion to U3O8 | 71-74 |
| Boron by Emission Spectrography | 75-81 |
| Impurity Elements by Spark Source Mass Spectrography | 82 |
| Isotopic Composition by Thermal Ionization Mass Spectrometry | 83 |
| Uranium-232 by Alpha Spectrometry | 84-90 |
| Total Alpha Activity by Direct Alpha Counting | 91-97 |
| Fission Product Activity by Beta Counting | 98-104 |
| Entrained Organic Matter by Infrared Spectrophotometry | 105 |
| Fission Product Activity by Gamma Counting | 106 |
| Determination of Arsenic | 107 |
| Determination of Impurities for the EBC Calculation | 108 |
| Determination of Technetium 99 | 109 |
| Determination of Plutonium and Neptunium | 110 |
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. Specific precautionary statements are given in Section 5. 7.1 Uranium can be determined using iron (II) reduction and dichromate titration. Test Method C1267 can be used. 7.2 Uranium can also be determined using cerium (IV) oxidation titrimetry. ISO 7097 Test Method can be used. 7.3 Uranium can also be determined by X-Ray Fluorescence using Test Method C1254. 7.4 Previous sections have been deleted. 8.1 This test method covers the determination of uranium in nuclear-grade uranyl nitrate solution. Appropriate size sample aliquots are chosen to obtain 5 to 10 g of U3O8. 15.1 This test method covers the determination of the specific gravity of a solution of uranyl nitrate to ±0.0004. 21.1 This test method covers the determination of the free acid content of uranyl nitrate solutions that may contain a ratio of up to 5 moles of acid to 1 mole of uranium. 28.1 The determination of thorium by the arsenazo (III) (photometric) method has been discontinued, (see C799-93). 28.2 As an alternative, thorium can be determined using Inductively Coupled Plasma Mass Spectrometry (ICP-MS). See Test Method C1287. 28.3 Previous sections have been deleted. 29.1 The determination of chromium by the diphenyl carbazide method has been discontinued, (see C799-93). 29.2 As an alternative, chromium can be determined using inductively coupled plasma atomic emission spectrometry (ICP-AES). Test Method C761 can be used providing a transformation to U3O8 so described hereafter in sections 117–120 A direct conversion to the amonium fluoride plus nitric acid solution can also be used, (see C761). 29.3 As an alternative, chromium can be determined using atomic absorption spectroscopy. Test Method C761 can be used. 29.4 As an alternative, chromium can be determined using ICP-MS. Test Method C1287 can be used. 29.5 Previous sections have been deleted. 30.1 The determination of molybdenum by the thiocyanate (photometric) method has been discontinued, (See C799-93). 30.2 As an alternative, molybdenum can be determined using ICP-MS. Test Method C1287 can be used. 30.3 As an alternative, molybdenum can be determined using ICP-AES. Test Method C761, sections 251 to 271 can be used providing a tranformation to U3O8 as described hereafter in sections 71-74. A direct conversion to the amonium fluoride plus nitric acid solution can also be used, (see C761, section 251). 30.4 Previous sections have been deleted. 31.1 This test method covers the separation of the halogens by means of a steam distillation. 36.1 This test method covers the determination of as low as 2 μg F/g U in distillate containing all the halogens. 43.1 The determination of chloride, bromide and iodide by microtitrimetric method has been discontinued, (see C799-93). 43.2 Previous sections have been deleted. 44.1 Determination of bromide by the fluorescein (photometric) method has been discontinued, (see C799-93). 44.2 As an alternative, bromide and chloride can be determined by X-Ray Fluorescence. Halogens are precipitated by silver nitrate and filtrated. The precipitate is washed and counted by X-Ray Fluorescence. 44.3 Previous sections have been deleted. 45.1 Sulfur can be determined using X-Ray Fluorescence. See Test Method C1296. 46.1 This test method covers the determination of the sulfur concentration, which exists as sulfate in uranyl nitrate solutions, in the range from 100 to 1000 μg S/g of uranium. 54.1 This test method covers determination of phosphorus in nuclear-grade uranyl nitrate solutions. Appropriate dilution may be made to facilitate obtaining samples containing 0 to 60 μg P. 62.1 This test method covers the determination of up to 20 μg Si (2 to 200 μg Si/g U) in uranyl nitrate solutions. 70.1 Determination of carbon by the persulfate oxidation titrimetry method has been discontinued, (see C799-93). 70.2 Previous sections have been deleted. 71.1 This test method is specifically designed for the conversion of uranyl nitrate to U3O8. 75.1 This test method covers the determination of 0.05 to 33 μg B/g of uranium. 82.1 The determination of impurities by spark source mass spectrography method has been discontinued, (see C799-93). 82.2 Previous section have been deleted. 83.1 The determination of isotopic composition using a single collector thermal ionisation mass spectrometer has been discontinued, (see C799-93 and C696). 83.2 As an alternative, the isotopic composition can be measured using a multi- collector thermal ionisation spectrometer. Test Method C1413 can be used. 83.3 As an alternative, the isotopic composition can be measured using isotope dilution mass spectormetry. Test Method C1380 can be used. 83.4 Previous section have been deleted. 84.1 This test method covers the determination of uranium-232 in nuclear-grade uranyl nitrate solutions, in concentrations as low as 0.05 ng 232U/ 235U. 91.1 This test method covers the determination of the sum of all alpha-emitting nuclides in uranyl nitrate solutions. 98.1 This test method covers the measurement of the beta emitters fission product activity of nuclear-grade uranyl nitrate solutions. 105.1 The determination of entrained organic matter by infrared spectrophotometry method has been discontinued, (see C799-93). 106.1 The determination of gamma emiters fission products can be done with Test Method C1295. 107.1 The determination of arsenic can be done with atomic absorption. Test Method C1219 can be used. 107.2 As an alternative, arsenic can be determined using ICP-MS. Test Method C1287 can be used. 108.1 The determination of impurities for the Equivalent Boron Content can be done with ICP-MS. Test Method C1287 can be used. The EBC table described in C1233 can be used. 109.1 The determination of Technetium 99 can be done using ICP-MS. Test Method C1287 can be used. 109.2 As an alternative, Technetium can be determined after solvent extraction by beta counting. Test Method C761 can be used. 110.1 Plutonium can be determined by alpha counting after ion exchange. Test Method C761 can be used. 110.2 As an alternative, plutonium can be determined by alpha counting after solvent extraction. Test Method C761 can be used. 110.3 Neptunium can be determined by alpha counting after solvent extraction. Test Method C761 can be used. 110.4 Previous sections have been deleted.