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A New Look at the Occurrences of the Rare-Earth Elements in the Georgia Kaolins

Published online by Cambridge University Press:  01 January 2024

W. Crawford Elliott ,
Daniel J. Gardner ,
Prakash Malla  and
Ed Riley
W. Crawford Elliott*
Affiliation:
Department of Geosciences, Georgia State University, Atlanta, GA 30302-3965, USA
Daniel J. Gardner
Affiliation:
Department of Geosciences, Georgia State University, Atlanta, GA 30302-3965, USA
Prakash Malla
Affiliation:
Thiele Kaolin Company, P.O Box 1056, Sandersville, GA 31082-1056, USA
Ed Riley
Affiliation:
Thiele Kaolin Company, P.O Box 1056, Sandersville, GA 31082-1056, USA
*
*E-mail address of corresponding author: [email protected]
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Abstract

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The high-density siliciclastic minerals (e.g. zircon) in the coarse fractions (>44 mm, informally known as grit) of the mined Georgia kaolins are potential and significant sources of the rare-earth elements (REE). The abundances and provenance of the REE signature have not been studied extensively for the Georgia kaolins. The objective of the present study was, therefore, to define the contribution of these heavy minerals (e.g. zircon) to the REE inventory of the coarse fractions of Georgia kaolins. Heavy-mineral subfractions separated from the coarse fractions contained 1647 mg/kg REE from the Jeffersonville Member of the Lower Tertiary Huber Formation and 5012 mg/kg REE from the Buffalo Creek Kaolin Member of the Upper Cretaceous Galliard Formation, respectively. These heavy-mineral subfractions were enriched 10–100 times in the heavy rare-earth elements (HREE, Gd—Lu,), Hf, and Zr relative to the concentrations of these elements in Upper Continental Crust. The heavy-mineral subfractions comprised 5% of the coarse fractions (grit) of these two kaolin-producing formations. The heavy-mineral subfractions consisted of zircon, anatase, rutile, kaolinite, and minor amounts of muscovite, trace ilmenite, and staurolite. The large concentrations of REE were obtained by separating the dense heavy minerals from the coarse fraction (grit) obtained during the typical production of kaolin-group minerals (kaolinite) from kaolin ore. The amount of zircon (estimated from the 6–11 wt.% Zr) and the absence of monazite did not explain the high concentrations of REE in the heavy-mineral subfractions. The large amounts of REE could have resulted from the sorption of REE released during weathering reactions, or from the presence of small amounts (0.025 wt.%) each of monazite and xenotime in addition to the presence of zircon. This heavymineral subfraction represented a novel domestic resource of extractable REE, especially the HREE, of a grade as high as 0.50 wt.% total REE.

Keywords

GeorgiaHeavy Mineral SeparationKaolinRare-Earth Elements
Type
Article
Information
Clays and Clay Minerals , Volume 66 , Issue 3 , June 2018 , pp. 245 - 260
Copyright
Copyright © Clay Minerals Society 2018

References

Anders, E. and Grevesse, N., 1989 Abundances of the elements: meteoritic and solar Geochimica et Cosmochimica Acta 53 197224.CrossRefGoogle Scholar
Aubert, D. Stille, P. and Probst, A., 2001 REE fractionation during granite weathering and removal by waters and suspected loads: Sr, Nd, isotopic evidence Geochimica et Cosmochimca Acta 65 387406.CrossRefGoogle Scholar
Awwiller, D.N. and Mack, L.E., 1991 Diagenetic modification of Sm-Nd model ages in Tertiary mudstones and shales, Texas Gulf Coast Geology 19 311314.2.3.CO;2>CrossRefGoogle Scholar
Banfield, J.F. and Eggleton, R.A., 1989 Apatite replacement and rare-earth mobilization, fractionation, and fixation during weathering Clays and Clay Minerals 37 113127.CrossRefGoogle Scholar
Bao, Z. and Zhao, Z., 2008 Geochemistry of mineralization with exchangeable REY in the weathering crusts of granitic rocks in South China Ore Geology Reviews 33 519533.CrossRefGoogle Scholar
Bea, F., 1996 Residence of REE, Y, Th and U in granites and crustal protoliths; Implications for the chemistry of crustal melts Journal of Petrology 37 521552.CrossRefGoogle Scholar
Bechtel, A. Ghazi, A.M. Elliott, W.C. and Osczcepalski, S., 2001 The occurrences of rare earth elements and the platinum group metals in relation to base metal zoning in vicinity to the Rote Fäule in the Kupferschiefer, Poland Applied Geochemistry 16 375386.CrossRefGoogle Scholar
Bern, C. Shah, A.K. Benzel, W.M. and Lowers, H.A., 2016 The distribution and composition of REE-bearing minerals in placers of the Atlantic and Gulf Coast Coastal Plains Journal of Geochemical Exploration 162 5061.CrossRefGoogle Scholar
Bern, C.R. Yesavage, T. and Foley, N.K., 2017 Ionadsorption REEs in regolith of the Liberty Hill pluton, South Carolina, USA: An effect of hydrothermal alteration Journal of Geochemical Exploration 172 2940.CrossRefGoogle Scholar
Bowman, W.S., 1995 Canadian diorite gneiss SY-4: Preparation and certification by eighty-nine laboratories Geostandards Newsletter 19 101124.CrossRefGoogle Scholar
Brown, G. Brindley, G.W., Brindley, G.W. and Brown, G., 1980 X-ray diffraction procedures for clay mineral identification Crystal Structures of Clay Minerals and their X-ray Identification London Monograph 5, Mineralogical Society 305360.CrossRefGoogle Scholar
Burkov, V.V. and Podporina, Ye, K., 1967 Rare-earths in granitoid residuum: Doklady Academy of Sciences, U.S.S.R. Earth Science Section 177 214216.Google Scholar
Carver, R.C., 1966 Stratigraphy of the Jackson Group (Eocene) Central Georgia Sedimentary Geology 7 8392.Google Scholar
Cheshire, M.C., 2011 Isotopic and geochemical composition of the Georgia kaolins: Insights into formation and diagenetic conditions. PhD dissertation Indiana, USA Indiana University, Bloomington.Google Scholar
China National Analysis Center for IronSteel, 2008 Certificate of Certified Reference Material NCS DC 86317 and NCSDC 86318 China National Accreditation of Geostandards .Google Scholar
Cullers, R.L. Chaudhuri, S. Kilbane, N. and Koch, R., 1979 Rare-earths in size fractions in sedimentary rocks of Pennsylvanian-Permian age from the mid-continent of the U.S.A Geochimica et Cosmochimica Acta 43 12851301.CrossRefGoogle Scholar
Dombrowski, T., 1992 The use of trace elements to determine provenance relations among different types of Georgia Kaolins. PhD dissertation Bloomington, Indiana Indiana University.Google Scholar
Dombrowski, T., Murray, H.H. Bundy, W.M. and Harvey, C.E., 1993 Theories of origin for the Georgia kaolins: A review Kaolin Genesis and Utilization Virginia, USA The Clay Minerals Society, Chantilly 75116.Google Scholar
Drost, D. and Wang, R., 2016.Rare-earth element criticality and sustainable management. 4th International Conference on Sensors, Measurement and Intelligent Materials (ICSMIM 2015)CrossRefGoogle Scholar
Elliott, W.C., 1993 Origin of the Mg-smectite at the Cretaceous-Tertiary (K/T) Boundary at Stevns Klint, Denmark Clays and Clay Minerals 41 442452.CrossRefGoogle Scholar
Elser, A.M., 2004 The provenance and weathering of muscovite from the Georgia kaolin deposits Atlanta, Georgia Georgia State University.Google Scholar
Elzea-Kogel, J.E. Pickering, S.M. Shelobolina, E. Chowns, T. Yuan, J. and Avant, D.M., 2000 The Geology of the Commercial Mining District of Central and Eastern Georgia Georgia Geological Society Guidebooks 20 344.Google Scholar
Epperson, E. and Elliott, W.C. (2018) Occurrence of the lanthanide rare earth elements in the Georgia Kaolins and heavy mineral sands. Geological Society of America Abstracts with Programs. Vol. 50, No. 3. 10.1130/abs/2018SE-313270.CrossRefGoogle Scholar
Flanagan, D.L., 2017 Clays: U.S. Geological Survey Mineral Commodity Summaries 5051.Google Scholar
Flanagan, J.F. (1984) Three USGS mafic rock reference samples: W-2, DNC-1, and BIR-1. United States Geological Survey Bulletin, 1623, 54 pp.Google Scholar
Flanagan, J.F. and Gottfried, D. (1980) USGS Rock standards III; Manganese nodule reference samples USGS Nod A-1, USGS Nod P-1. US Geological Survey Professional Paper, 1155, 39 pp.Google Scholar
Foley, N. and Ayuso, R., 2015 REE enrichment in granitederived regolith deposits of the Southeastern United States: Prospective source rocks and accumulation processes British Columbia Geological Survey Paper 3 131138.Google Scholar
Fullagar, P.D. and Butler, J.R., 1976 Petrochemical and geochronologic studies of plutonic rocks in the southern Appalachians: II, The Sparta granite complex, Georgia Geological Society of America Bulletin 87 5356.2.0.CO;2>CrossRefGoogle Scholar
Gambogi, J., 2017 Rare-earths. US Geological Survey Mineral Commodity Summaries 134135.Google Scholar
Gardner, D.J., 2016 A study of mineral impurities within the Georgia Kaolins: Unpublished MS thesis Atlanta, Georgia, USA Georgia State University.Google Scholar
Gromet, P. Dymek, R.F. Haskin, L.A. and Korote, R.L., 1984 The “North American shale composite”: Its compilation, major and trace element characteristics Geochimica et Cosmochimica Acta 48 24692482.CrossRefGoogle Scholar
Herrmann, W. and Berry, R.F., 2002 MINSQ — a least squares spreadsheet method for calculating mineral proportions from whole rock major element analyses Geochemistry, Exploration, Environment 2 361368.CrossRefGoogle Scholar
Hoskin, P.W.O. and Schaltegger, U., 2003 The composition of zircon and igneous and metamorphic petrogenesis Zircon 53 2762.CrossRefGoogle Scholar
Huddlestun, P.F. and Hetrick, J.H., 1979 The stratigraphy of the Barnwell Group of Georgia. Georgia Geological Survey Open File Report 80-1 1725.Google Scholar
Huddlestun, P.F. and Hetrick, J.H. (1991) The stratigraphic framework of the Fort Valley Plateau and the Central Georgia kaolin district. Guidebook of the 26th Annual Meeting of the Georgia Geological Society. Georgia Geological Society, 11, no. 1, 119 pp. (Summary available at ; accessed March 18, 2018).Google Scholar
Hurst, V.J. Pickering, S.M. Jr, 1997 Origin and classification of coastal plain kaolins, Southeastern USA, and the role of groundwater and microbial action Clays and Clay Minerals 45 274285.CrossRefGoogle Scholar
Imai, N. Terashima, S. Itoh, S. and Nado, A., 1995 1994 compilation of analytical data for minor and trace elements in seventeen GSJ geochemical reference samples Geostandards Newsletter 19 135213.CrossRefGoogle Scholar
Jackson, M.L., 1985 Soil Chemical Analysis: Advanced Course Madison, Wisconsin, USA Published by the author..Google Scholar
Jones, L.M. and Walker, R.L., 1973 Rb-Sr whole-rock age of the Siloam granite, Georgia: A Permian intrusive in the southern Appalachians Geological Society of America Bulletin 84 36533658.2.0.CO;2>CrossRefGoogle Scholar
Kulp, J.L. and Eckelman, F.D., 1961 Potassium-argon ages of micas from the southern Appalachian Annals of the New York Academy of Sciences 91 408416.CrossRefGoogle Scholar
Kynicky, J. Smith, M.P. and Xu, C., 2012 Diversity of rareearth deposits, the key example of China Elements 8 361367.CrossRefGoogle Scholar
Lang, W.B., Warren, W.C., Thompson, R.M., and Overstreet, E.F. (1965) Bauxite and kaolin deposits of the Irwinton District, Georgia. US Geological Survey Bulletin, 1199, 34 pp.Google Scholar
Lev, S.M. McLennan, S.M. and Hanson, G.N., 1999 Mineralogic controls of REE mobility during back shale diagenesis Journal of Sedimentary Research 69 10711082.CrossRefGoogle Scholar
Li, L.Z. Yang, Z., De Lima, I.B. and Filho, W.L., 2016 China’s rare-earth resources, mineralogy and beneficiation Rare-earths Industry Technological, Economic and Environmental Implications Amsterdam Elsevier 139150.CrossRefGoogle Scholar
Long, K.R. Van Gosen, B.S. Foley, N.K. and Cordier, D., 2016.The principal rare-earth elements deposits of the United States — A summary of domestic deposits and a global perspective Scientific Investigations Report 2010-5220CrossRefGoogle Scholar
Ma, L. Jin, L. and Brantley, S.L., 2011 How mineralogy and slope aspect affect REE release and fractionation during shale weathering in the Susquehanna/Shale Hills Critical Zone Observatory Chemical Geology 290 3149.CrossRefGoogle Scholar
McLennan, S.M., Lipin, B.R. and McKay, G.A., 1989 Rare-earth elements in sedimentary rocks: Influences of provenance and sedimentary processes Geochemistry and Mineralogy of Rareearth Elements Washington D.C. Mineralogical Society of America 169200.CrossRefGoogle Scholar
Moldoveanu, G.A. and Papangelakis, V.G., 2012 Recovery of rare-earth elements adsorbed on clay minerals: Desorption mechanism Hydrometallurgy 117-118 7178.CrossRefGoogle Scholar
Moore, D.M. Reynolds, R.C. Jr, 1997 X-ray Diffraction and the Identification and Analysis of Clay Minerals second edition New York Oxford University Press.Google Scholar
Murray, H.H., 1976 The Georgia sedimentary kaolins: The 7th Symposium of Genesis of Kaolins [Scientific Report] 114125.Google Scholar
Murray, H.H. (2007) Applied clay mineralogy: Occurrences, processing and application of kaolins, bentonites, palygorskite-sepiolite and common clays. Developments of Clay Science 2, 180 pp.Google Scholar
Ohr, M. Halliday, A.N. and Peacor, D.R., 1994 Mobility and fractionation of rare-earth elements in argillaceous rocks sediments: Implications for dating diagenesis and low-grade metamorphism Geochimica et Cosmochimica Acta 58 289312.CrossRefGoogle Scholar
Oszczepalski, S. Chmielewsik, A. and Mikulski, S.Z., 2016 Controls on the distribution of rare earth elements in the Kupferschiefer series of SW Poland Geological Quarterly 60 811826.Google Scholar
Ore ResearchExploration Pty Ltd., 2008a Uraniumbearing multi-element reference material. OREAS 100a: Report 08/719A .Google Scholar
Ore ResearchExploration Pty Ltd., 2008b Uraniumbearing multi-element reference material. OREAS 101a: Report 08/719B .Google Scholar
Papoulis, D. Tsolis-Katagas, P. and Katagas, C., 2004 Monazite alteration mechanisms and depletion measurements in kaolins Applied Clay Science 24 271285.CrossRefGoogle Scholar
Pickering, S.M. Jr, 1976 Geologic Map of Georgia USA Georgia Department of Natural Resources.Google Scholar
Piper, D.Z. and Bau, M., 2013 Normalized rare-earth elements in water, sediments, and wine: Identifying sources and environmental redox conditions American Journal of Analytical Chemistry 4 6983.CrossRefGoogle Scholar
Prasad, M.S. Reid, K.J. and Murray, H.H., 1991 Kaolin: processing, properties, and applications Applied Clay Science 6 87119.CrossRefGoogle Scholar
Rozelle, P.L. Khadilkar, A.B. Pulati, N. Soundarrajan, N. Klima, M.S. Mosser, M.M. and Pisupati, S.V., 2016 A study on removal of rare-earth elements from US coal byproducts by ion exchange Metallurgical and Materials Transactions E 3 617.CrossRefGoogle Scholar
Rudnick, R.L. and Gao, R. (2003) Composition of the continental crust. Pp. 164 in: The Crust (Crust, T.h.e., editor). Treatise of Geochemistry, 3, Elsevier-Pergamon, Oxford, UK.Google Scholar
Schroder, C.H. (1982) Trace fossils of the Oconee Group and basal Barnwell Group of east-central Georgia. Georgia Geological Survey Bulletin, 88, 136 pp. ().Google Scholar
Schroeder, P.A. and Shiflet, J., 2000 Ti bearing phases in the Huber formation, and east Georgia kaolin deposit Clays and Clay Minerals 48 151158.CrossRefGoogle Scholar
Shearer, H.K., 1917 A report on the bauxite and fullers earth of the Coastal Plain of Georgia Georgia Geological Survey Bulletin 31 158163.Google Scholar
Shelobolina, E. Parfenova, Y. and Avakyan, Z.A., 1999 Microorganisms of kaolins and their role in the process of iron solubilization and transformation Process Metallurgy 9 559568.CrossRefGoogle Scholar
Smith, J.W. Wampler, J.M. and Green, M.A., 1969 Isotopic dating and metamorphic isograds of the crystalline rocks of Georgia Precambrian Appalachian problems 80 123129.Google Scholar
Snoke, A.W. Kish, S.A. and Secor, D.J., 1980 Deformed Hercynian granitic rocks from the Piedmont of South Carolina American Journal of Science 280 10181034.CrossRefGoogle Scholar
Sousa, D.J.L. Varajão, AFDC and Yvon, J., 2006 Geochemical evolution of the Capim River kaolin, northern Brazil Journal of Geochemical Exploration 88 329331.CrossRefGoogle Scholar
Speer, J.A., 1982 Zircon Orthosilicates 5 67112.CrossRefGoogle Scholar
Totten, M.W. Hannan, M.A. Mack, D. and Borges, J., 2002 Characteristics of mixed-layer smectite/illite density separates during burial diagenesis American Mineralogist 87 15711579.CrossRefGoogle Scholar
Trail, D. Watson, E.B. and Tailby, N.D., 2012 Ce and Eu anomalies in zircon as proxies for the oxidation state of magmas Geochimica et Cosmochimica Acta 97 7087.CrossRefGoogle Scholar
United States Geological Survey, 2016 The Mineral Industry of Georgia: 2012–2013 Minerals Yearbook Georgia .Google Scholar
Virta, ^R.L., 2015 Clay and shale [Advanced Release]: 2013 Minerals Yearbook United States Department of Interior 18.118.22.Google Scholar
Watson, E.B. Wark, D.A. and Thomas, J.B., 2006 Crystallization thermometers for zircon and rutile Contributions to Mineralogy and Petrology 151 413433.CrossRefGoogle Scholar
Weng, X. Lei, Y. Ge, J. and Wu, W., 2015 Production forecast of China Rare-earths based on the generalized Weng model and policy recommendations Resources Policy 43 1118.CrossRefGoogle Scholar