Distribution of rare earth elements in the pilot-scale processing of fly ashes derived from eastern Kentucky coals: Comparisons of the feed and processed ashes

•Pilot-scale extraction of REE from beneficiated Central Appalachian-derived fly ash was performed.•REE and several minor elements and major oxides are depleted in the spent, post-extraction ash.•Gd, Nd, and Dy are well differentiated between the feed and spent ashes.•Heavy REE and Y are disproporti...

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Published inFuel (Guildford) Vol. 295; no. C; p. 120562
Main Authors Hower, James C., Groppo, John G., Jewell, Robert B., Wiseman, John D., Duvallet, Tristana Y., Oberlink, Anne E., Hopps, Shelley D., Morgan, Tonya D., Henke, Kevin R., Joshi, Prakash, Preda, Dorin V., Gamliel, David P., Beers, Todd, Schrock, Michael
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.07.2021
Elsevier BV
Elsevier
Subjects
Ashes
Beneficiation
Coal
Compressive strength
Depletion
Ferric oxide
Fly ash
Gadolinium
Lanthanides
Leachates
Mineral processing
Phosphorus pentoxide
Portland cement
Portland cements
Rare earth elements
Scandium
Sulfur trioxide
Trace elements
Yttrium
Fly ash
Beneficiation
Lanthanides
Coal
Mineral processing
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Summary:•Pilot-scale extraction of REE from beneficiated Central Appalachian-derived fly ash was performed.•REE and several minor elements and major oxides are depleted in the spent, post-extraction ash.•Gd, Nd, and Dy are well differentiated between the feed and spent ashes.•Heavy REE and Y are disproportionately concentrated in the final product.•Cementitious properties of the spent ash + ordinary Portland cement mixes are retained. Beneficiated fly ash from the combustion of Central Appalachian high volatile bituminous coals was extracted with HNO3 in a pilot-scale processing plant. Several major oxides (notably CaO and SO3, but also including Fe2O3, MgO, K2O, and P2O5) and minor elements (Mn, As, Sr, Ba, and Pb) are depleted in the post-HNO3-extraction spent ash. The total lanthanides, Y, and Sc concentration is reduced by about 20% in the spent ash, with Gd showing the greatest decrease. Along with Gd, Nd and Dy are also well differentiated between the feed and spent ashes, with La and Sm showing minimal partitioning. The Gd decrease is correlated with the depletion of Fe2O3. The heavy rare earth elements (REE heavier than Eu) and Y are disproportionately concentrated in the HNO3-leachate compared to the light REE. For the ashes studied, Sc did not partition between the feed and spent ashes. Pozzolanicity tests show that the compressive strength and strength activity indices of the spent ash + ordinary Portland cement (OPC) mixes are comparable to 100% OPC, indicating that the spent ashes produced in the pilot-scale runs have the potential to be sold as a Class F fly ash. Ultimately, the beneficiated ash chemistry influences the chemistry of the post-HNO3-extraction spent ash and the HNO3-leachate. A 500-ppm-REE fly ash will presumably be a more economically favorable feedstock than an ash with a significantly lesser concentration.
Bibliography:USDOE
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2021.120562