Radiotracer Study of the Preparation of High-Purity Lanthanum Fluoride

The behavior of the impurities iron, cobalt, yttrium, and cerium is determined via radiotracer techniques for the preparation of high‐purity lanthanum fluoride. The behavior of nickel and copper during the coprecipitation of a lanthanum nitrate solution is determined by graphite furnace atomic absor...

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Bibliographic Details
Published in:Journal of the American Ceramic Society 1992-06, Vol.75 (6), p.1562-1565
Main Authors: Ewing, Kenneth J., Jaganathan, James, Peitersen, Laura, Aggarwal, Ishwar D., Sommers, James A., Fahey, Jeff V.
Format: Article
Language:English
Subjects:
400201 - Chemical & Physicochemical Properties
ABSORPTION SPECTROSCOPY
CERIUM
CHEMICAL PREPARATION
COBALT
COPPER
COPRECIPITATION
ELEMENTS
FLUORIDES
FLUORINE COMPOUNDS
GLASS
HALIDES
HALOGEN COMPOUNDS
IMPURITIES
INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY
IRON
ISOTOPE APPLICATIONS
lanthanum
LANTHANUM COMPOUNDS
LANTHANUM FLUORIDES
LANTHANUM NITRATES
METALS
NEODYMIUM
NICKEL
NITRATES
NITROGEN COMPOUNDS
oxides
OXYGEN COMPOUNDS
PRECIPITATION
purification
RARE EARTH COMPOUNDS
RARE EARTHS
SEPARATION PROCESSES
SPECTROSCOPY
STRUCTURAL CHEMICAL ANALYSIS
SYNTHESIS
TRACER TECHNIQUES
TRANSITION ELEMENTS
YTTRIUM
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Summary:The behavior of the impurities iron, cobalt, yttrium, and cerium is determined via radiotracer techniques for the preparation of high‐purity lanthanum fluoride. The behavior of nickel and copper during the coprecipitation of a lanthanum nitrate solution is determined by graphite furnace atomic absorption spectrometric (GFAAS) analysis. There is no commercially available radiotracer for neodymium, a key impurity associated with absorption losses in fluoride glasses. However, the chemical behavior of neodymium and that of yttrium are very similar and, therefore, it is resonable to assume that the behavior of yttrium throughout the processing is indicative of the behavior of neodymium. The concentrations of impurities in lanthanum nitrate, carbonate, and fluoride are estimated using the radiotracer and GFAAS data for each processing step. Results indicate that while high‐purity lanthanum carbonate can be prepared, any impurities present in the lanthanum carbonate will be carried quantitatively into lanthanum fluoride upon hydrofluorination. The data also indicate that lanthanum nitrate can be prepared in higher purity than lanthanum carbonate; however, lanthanum fluoride prepared from the nitrate forms a very wet precipitate which is extremely difficult to filter and dry. The presence of excess water in lanthanum fluoride results in high levels of oxide contamination in lanthanum fluoride as well as the fluoride glass. Preparation of low‐oxide lanthanum fluoride is required because high oxide levels in fluoride glasses cause increased scattering. Therefore, from a fluoride glass point of view, the preferred synthetic route for the preparation of high‐purity lanthanum fluoride is to first purify lanthanum nitrate, then convert this to the carbonate, which is then converted to lanthanum fluoride. The estimated impurity concentrations in lanthanum fluoride derived from lanthanum carbonate are as follows: Fe, 89 ng/g; Co,
ISSN:0002-7820
1551-2916
DOI:10.1111/j.1151-2916.1992.tb04225.x