Radionuclides, trace elements, and radium residence in phosphogypsum of Jordan

Radionuclides, trace elements, and radium residence in phosphogypsum of Jordan

Voluminous stockpiles of phosphogypsum (PG) generated during the wet process production of phosphoric acid are stored at many sites around the world and pose problems for their safe storage, disposal, or utilization. A major concern is the elevated concentration of long-lived 226 Ra (half-life = 1,6...

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Bibliographic Details
Published in:Environmental geochemistry and health Vol. 33; no. 2; pp. 149 - 165
Main Authors: Zielinski, Robert A., Al-Hwaiti, Mohammad S., Budahn, James R., Ranville, James F.
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-04-2011
Springer Nature B.V
Subjects:
Barium
Barium Sulfate - analysis
Calcium Sulfate - analysis
Chemical elements
Earth and Environmental Science
Environment
Environmental Chemistry
Environmental Health
Geochemistry
Industrial Waste
Jordan
Leaching
Metals, Rare Earth - analysis
Original Paper
Phosphorus - analysis
Phosphorus content
Public Health
Radioactive half-life
Radioisotopes - analysis
Radium
Radium - analysis
Radon
Rare earth elements
Rocks
Soil Pollutants, Radioactive - analysis
Soil Pollutants, Radioactive - chemistry
Soil Science & Conservation
Solubility
Terrestrial Pollution
Trace elements
Water - analysis
Water - chemistry
Water Pollutants, Radioactive - analysis
Water Pollutants, Radioactive - chemistry
Jordan
Phosphogypsum
Barite
Rare earth elements
Radiobarite
Jordan
Radium
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Summary:Voluminous stockpiles of phosphogypsum (PG) generated during the wet process production of phosphoric acid are stored at many sites around the world and pose problems for their safe storage, disposal, or utilization. A major concern is the elevated concentration of long-lived 226 Ra (half-life = 1,600 years) inherited from the processed phosphate rock. Knowledge of the abundance and mode-of-occurrence of radium (Ra) in PG is critical for accurate prediction of Ra leachability and radon (Rn) emanation, and for prediction of radiation-exposure pathways to workers and to the public. The mean (±SD) of 226 Ra concentrations in ten samples of Jordan PG is 601 ± 98 Bq/kg, which falls near the midrange of values reported for PG samples collected worldwide. Jordan PG generally shows no analytically significant enrichment (<10%) of 226 Ra in the finer (<53 μm) grain size fraction. Phosphogypsum samples collected from two industrial sites with different sources of phosphate rock feedstock show consistent differences in concentration of 226 Ra and rare earth elements, and also consistent trends of enrichment in these elements with increasing age of PG. Water-insoluble residues from Jordan PG constitute <10% of PG mass but contain 30–65% of the 226 Ra. 226 Ra correlates closely with Ba in the water-insoluble residues. Uniformly tiny (<10 μm) grains of barite (barium sulfate) observed with scanning electron microscopy have crystal morphologies that indicate their formation during the wet process. Barite is a well-documented and efficient scavenger of Ra from solution and is also very insoluble in water and mineral acids. Radium-bearing barite in PG influences the environmental mobility of radium and the radiation-exposure pathways near PG stockpiles.
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ISSN:0269-4042
1573-2983
DOI:10.1007/s10653-010-9328-4