Rare Earth Elements Recovery and Sulphate Removal from Phosphogypsum Waste Waters with Sulphate Reducing Bacteria

Jarno Mäkinen; Malin Bomberg; Marja Salo; Mona Arnold; Pertti Koukkari

doi:10.4028/www.scientific.net/SSP.262.573

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Optimization of Bioscorodite Crystallization for Treatment of As(III)-Bearing Wastewaters
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Microbial Production of Schwertmannite: Development from Microbial Fundamentals to Marketable Products
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Rare Earth Elements Recovery and Sulphate Removal from Phosphogypsum Waste Waters with Sulphate Reducing Bacteria
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HomeSolid State PhenomenaSolid State Phenomena Vol. 262Rare Earth Elements Recovery and Sulphate Removal...

Rare Earth Elements Recovery and Sulphate Removal from Phosphogypsum Waste Waters with Sulphate Reducing Bacteria

Abstract:

Phosphogypsum waste, originating from phosphoric acid production from apatite ores, is well known for its high production rate and possible release of sulphate-rich seepage waters. In addition to negative environmental impacts, phosphogypsum waste heaps are also remarkable secondary sources of Rare Earth Elements (REE); in the phosphoric acid production process a majority of REE, occurring in apatite, are precipitated to the phosphogypsum waste. Therefore, a method treating both sulphate-rich waters and recovering REE from phosphogypsum heaps and seepage waters would offer both economic and environmental benefits. In this ongoing study, seepage waters from a phosphogypsum heap are treated with Sulphate Reducing Bacteria (SRB) and ethanol as a substrate. Sulphate is first reduced to hydrogen sulphide, which then precipitates REE as sulphides. The main challenge, low concentration of REE in seepage waters (e.g. 2.87 μg/l La, 5.13 μg/l Ce, 0.67 μg/l Y and 3.32 μg/l Nd), is overcome by utilizing continuous mode, semi-passive and cost effective column apparatus, requiring no agitation and performing both sulphate reduction and REE recovery in a single reactor. The SRB method results in a sulphate reduction rate of 40-80 % (from app. 1400 mg/l to 276-844 mg/l sulphate in the effluent) and efficient REE recovery from seepage water. The concentrate obtained from the column consists of a mixture of anaerobic sludge and precipitated REE, with respective REE concentrations of 202 mg/kg La, 477 mg/kg Ce, 49 mg/kg Y and 295 mg/kg Nd.

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Solid State Phenomena (Volume 262)

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573-576

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https://doi.org/10.4028/www.scientific.net/SSP.262.573

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Online since:

August 2017

Authors:

Jarno Mäkinen*, Malin Bomberg, Marja Salo, Mona Arnold, Pertti Koukkari

Keywords:

Apatite, Phosphogypsum, Rare Earth Element, Sulfate Reducing Bacteria (SRB), Sulphate

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