S.A. Reynolds scite author profile

Various criteria for radiochemical methods and standards must be considered in applying them in analysis of water. A method must insure that a given radionuclide is in the proper chemical state, e.g., the same as that of a stable carrier, if used. Methods for many elements contain steps to meet this criterion. Losses of radioelements, particularly in preliminary handling, must be avoided. Such losses may be caused by volatization or surface sorption. Difficulties caused by these effects have been frequently observed.The best standard for measurement of a particular nuclide is a known amount of that nuclide, and calibration should be done by a technique identical with that used for unknowns. Suitable standard solutions are available from the National Bureau of Standards and other suppliers. Scattering, sample size, positioning ("geometry"), and other factors are to be considered when doing alpha, beta, and gamma counting, and gamma spectrometry. In measuring "gross" activity, or activity of a nuclide of which a known quantity is not available, selection of a standard becomes difficult. Certain nuclides have been adopted for this purpose by various groups. Some advantages and disadvantages of each of these must be kept in mind.

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SR19021 Tritium Aging of Regenerated LANA.75 (Final Project Report)

Reynolds¹

2021

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The Savannah River Tritium Enterprise (SRTE) has used the metal hydride LaNi4.25Al0.75 (LANA.75) in the Tritium Facilities for over two decades. LANA.75 beds store significant quantities of tritium but have a limited service life due to the radiolytic decay of tritium to He-3 within the metal matrix. It has been shown that heating tritium-aged LANA.75 under vacuum can reverse tritium aging effects, eliminating the heel of trapped hydrogen, and restoring the reversible capacity. Additional investigation is needed to ensure there are no unexpected changes to the hydride before this restoration technique is employed in full scale beds in the Tritium Facilities.This project was to be comprised of three distinct scopes: obtain tritium aging data on the sample regenerated in 2018, regenerate a tritium-aged sample at 600 °C, and perform thermal stability testing on a non-tritiated sample. Isotherms were collected on the previously regenerated sample after approximately two years of tritium aging. Isotherms were collected at 80, 100, and 120 °C. As expected, there was a decrease in the plateau pressure, an increase in plateau slope, and a portion of the "heel" of tritium trapped in the metal had been reestablished. Unexpectedly, it appeared that the plateau had shortened at the higher tritium to metal ratios as well. This is typically seen in older samples.The second scope, to regenerate a second tritium-aged LANA.75 sample, was not completed. A Task Technical and Quality Assurance Plan was written and approved, a high temperature test cell was fabricated, several pre-job briefs were held, and the hydride sample was passivated with air. Despite these successes, the hydride sample was not recovered from the legacy test cell. Revision vii

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Radioactive sources; radioactive chemicals

Reynolds¹

1961

The International Journal of Applied Radiation and Isotopes

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SR19021 Tritium Aging of Regenerated LANA.75 (Final Project Report)

Staack¹,

Reynolds²

2021

0

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The Savannah River Tritium Enterprise (SRTE) has used the metal hydride LaNi4.25Al0.75 (LANA.75) in the Tritium Facilities for over two decades. LANA.75 beds store significant quantities of tritium but have a limited service life due to the radiolytic decay of tritium to He-3 within the metal matrix. It has been shown that heating tritium-aged LANA.75 under vacuum can reverse tritium aging effects, eliminating the heel of trapped hydrogen, and restoring the reversible capacity. Additional investigation is needed to ensure there are no unexpected changes to the hydride before this restoration technique is employed in full scale beds in the Tritium Facilities.This project was to be comprised of three distinct scopes: obtain tritium aging data on the sample regenerated in 2018, regenerate a tritium-aged sample at 600 °C, and perform thermal stability testing on a non-tritiated sample. Isotherms were collected on the previously regenerated sample after approximately two years of tritium aging. Isotherms were collected at 80, 100, and 120 °C. As expected, there was a decrease in the plateau pressure, an increase in plateau slope, and a portion of the "heel" of tritium trapped in the metal had been reestablished. Unexpectedly, it appeared that the plateau had shortened at the higher tritium to metal ratios as well. This is typically seen in older samples.The second scope, to regenerate a second tritium-aged LANA.75 sample, was not completed. A Task Technical and Quality Assurance Plan was written and approved, a high temperature test cell was fabricated, several pre-job briefs were held, and the hydride sample was passivated with air. Despite these successes, the hydride sample was not recovered from the legacy test cell. Revision vii

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S.A. Reynolds

Determination of Protactinium-233

Methods and Standards in Radioanalysis of Water

SR19021 Tritium Aging of Regenerated LANA.75 (Final Project Report)

Radioactive sources; radioactive chemicals

SR19021 Tritium Aging of Regenerated LANA.75 (Final Project Report)

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