Sources and Level of Rare Earth Element Contamination of Atmospheric Dust in Nigeria

Background. Rare earth element (REE) composition of atmospheric dust has recently been used to trace potential sources of dust pollution. Objective. The present study aimed to determine the sources of atmospheric pollution in the study area using REE patterns and determine their level of pollution. Methods. Twenty-five (25) atmospheric dust samples were collected in the study area, with five samples each from an industrial area, traffic area, dumpsite area, residential area and remote area in Ibadan, southwestern Nigeria. In addition, five (5) topsoil and two (2) rock samples (granite gneiss) were collected for comparison. Concentrations of REE were determined by inductively coupled plasma mass spectrometry (ICP-MS). Results. The ratio of lanthanum/cerium (La/Ce), especially in some locations in industrial area (1.5), traffic area (1.5) and to some extent dumpsite area (1.1) was higher than in soil (0.2), upper continental crust (0.5) and the minimum value of fluid catalytic crackers (1.0). Generally, the respective average values of the ratios of La/praseodymium (Pr), La/neodymium (Nd) and La/samarium (Sm) in industrial area (32.1, 7.8 and 52.6) and traffic area (14.9, 4.4 and 26.8) were higher than their respective averages in soil (4.4, 1.1 and 6.2), rock (5.7, 1.9 and 14.1), upper continental crust (4.4, 1.1 and 6.6) and the minimum value in fluid catalytic crackers (5.8, 3.7 and 37.0). Meanwhile, their corresponding value in the dumpsite area, residential area and remote area were lower or similar to the geological background levels. Discussion. The contamination factors of REEs in the atmospheric dust of the industrial area and traffic area were classified as heavily contaminated, especially with light lanthanoid elements in REE. The degree of contamination of REEs in the atmospheric dust of industrial area (30.9) and traffic area (18.8) fell within the considerable contamination category. The high values of the light lanthanoid ratio and the contamination indices were attributed to their emission from the fired-power plant and vehicular exhaust. Conclusions. Most of the composition of the atmospheric dust was sourced from the local geology of the study area as observed in the residential area and remote area, while the contamination in the industrial area and traffic area was attributed to human activities. Competing Interests. The authors declare no competing financial interests.

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Use of rare earth element patterns to trace the provenance of the atmospheric dust near Beijing, China

Environmental Earth Sciences ◽

10.1007/s12665-012-1791-z ◽

2012 ◽

Vol 68 (3) ◽

pp. 871-879 ◽

Cited By ~ 17

Author(s):

Yang Tang ◽

Guilin Han ◽

Qixin Wu ◽

Zhifang Xu

Keyword(s):

Rare Earth ◽

Rare Earth Element ◽

Earth Element ◽

Atmospheric Dust ◽

Beijing China

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Investigation of sources of atmospheric dust in Guiyang City, southwest China using rare earth element patterns

Journal of Earth System Science ◽

10.1007/s12040-019-1273-8 ◽

2019 ◽

Vol 129 (1) ◽

Author(s):

Yang Tang ◽

Guilin Han

Keyword(s):

Rare Earth ◽

Rare Earth Element ◽

Earth Element ◽

Southwest China ◽

Atmospheric Dust ◽

Guiyang City

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Rare earth element mobilization from marine atmospheric dust into seawater

Marine Chemistry ◽

10.1016/0304-4203(94)90081-7 ◽

1994 ◽

Vol 46 (3) ◽

pp. 255-260 ◽

Cited By ~ 86

Author(s):

M.J. Greaves ◽

P.J. Statham ◽

H. Elderfield

Keyword(s):

Rare Earth ◽

Rare Earth Element ◽

Earth Element ◽

Atmospheric Dust ◽

Element Mobilization

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The tonalite–trondhjemite–granodiorite (TTG) to granodiorite–granite (GG) transition in the late Archean plutonic rocks of the central Wyoming Province

Canadian Journal of Earth Sciences ◽

10.1139/e06-082 ◽

2006 ◽

Vol 43 (10) ◽

pp. 1419-1444 ◽

Cited By ~ 52

Author(s):

Carol D Frost ◽

B Ronald Frost ◽

Robert Kirkwood ◽

Kevin R Chamberlain

Keyword(s):

Rare Earth ◽

Continental Crust ◽

Rare Earth Element ◽

Earth Element ◽

Gradual Transition ◽

Heavy Rare Earth Element ◽

Isotopic Compositions ◽

Similar Range ◽

Wyoming Province ◽

Ree Patterns

The 2.95–2.82 Ga quartzofeldspathic gneisses and granitoids in the Bighorn, western Owl Creek, and northeastern Wind River uplifts in the central Wyoming Province include low-K tonalite–trondhjemite–granodiorite (TTG) and high-K granodiorite–granite (GG) rocks. Both types of granitoids were intruded contemporaneously, although TTGs are more abundant in the older gneisses. The TTG suite consists of calcic to marginally calc-alkalic rocks that straddle the boundaries between metaluminous and peraluminous and between ferroan and magnesian compositions. Rare-earth element (REE) patterns of these rocks may be highly fractionated with low heavy rare-earth element (HREE) contents and modest to absent Eu anomalies but may also be less strongly HREE depleted. These rocks do not represent first-generation continental crust: most have unradiogenic Nd and radiogenic 207Pb/204Pb isotopic compositions that require the incorporation of isotopically evolved sources. The GG suite has compositions that are transitional between Archean TTG and modern, continental margin calc-alkalic rocks. The GG suite is characterized by higher alkali contents relative to CaO than the TTG suite and higher K/Na ratios but exhibits a similar range in REE patterns. The Nd, Sr, and Pb isotopic compositions of the GG suite are slightly less variable but lie within the range of those of the TTG suite. We interpret them as having a source similar to that of the TTG, perhaps forming by partial melting of preexisting TTG. The shift from TTG-dominated to GG-dominated continental crust was a gradual transition that took place over several hundred million years. Clearly subduction-related calc-alkalic magmatism is not recognized in the Wyoming Province prior to 2.67 Ga.

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Trace Element and Stable Isotope Geochemistry of Lwamondo and Zebediela Kaolins, Limpopo Province, South Africa: Implication for Paleoenvironmental Reconstruction

Minerals ◽

10.3390/min9020093 ◽

2019 ◽

Vol 9 (2) ◽

pp. 93

Author(s):

Avhatakali Raphalalani ◽

Georges-Ivo Ekosse ◽

John Odiyo ◽

Jason Ogola ◽

Nenita Bukalo

Keyword(s):

Trace Elements ◽

Rare Earth ◽

Stable Isotope ◽

Trace Element ◽

Continental Crust ◽

Rare Earth Element ◽

Earth Element ◽

Paleoenvironmental Reconstruction ◽

Δ18o And Δd ◽

Ree Patterns

The aim of the present study was the paleoenvironmental reconstruction of the prevailing environment under which the Lwamondo and Zebediela kaolin deposits were formed. Hence, this study reports deuterium and oxygen stable isotope values and trace and rare earth element concentrations for two samples of kaolin. Upper continental crust-normalised trace-element patterns reveal that large ion lithophile elements and high-field-strength elements are generally depleted in Lwamondo and Zebediela kaolins, whereas transition trace elements are generally enriched in these kaolins. Upper continental crust-normalised rare earth element (REE) patterns show that there is a slight enrichment of heavy REEs (HREEs) compared to light REEs (LREEs) in these kaolins. The δ18O and δD stable isotope values for kaolinite from Lwamondo ranged from 17.4‰ to 19.1‰ and from −54‰ to 84‰, respectively, whereas those values for kaolinite from Zebediela varied from 15.6‰ to 17.7‰ and from −61‰ to –68‰ for δ18O and δD, respectively. The REE patterns and the content of other trace elements indicate ongoing kaolinitisation in the Lwamondo and Zebediela kaolins with minimum mineral sorting. The sources of the kaolins varied from basic to acidic and these were derived from an active margin tectonic setting. Lwamondo kaolin was deposited in an oxic environment whereas Zebediela kaolin was deposited under suboxic/anoxic conditions. Based on the δ18O and δD values of the kaolinite, they formed in a supergene environment at temperatures generally below 40 °C.

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Rare earth element-thorium correlations in sedimentary rocks, and the composition of the continental crust

Geochimica et Cosmochimica Acta ◽

10.1016/0016-7037(80)90232-x ◽

1980 ◽

Vol 44 (11) ◽

pp. 1833-1839 ◽

Cited By ~ 209

Author(s):

Scott M. McLennan ◽

W.B. Nance ◽

S.R. Taylor

Keyword(s):

Rare Earth ◽

Continental Crust ◽

Rare Earth Element ◽

Earth Element ◽

Sedimentary Rocks

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The composition and evolution of the continental crust: rare earth element evidence from sedimentary rocks

Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences ◽

10.1098/rsta.1981.0119 ◽

1981 ◽

Vol 301 (1461) ◽

pp. 381-399 ◽

Cited By ~ 529

Keyword(s):

Rare Earth ◽

Partial Melting ◽

Continental Crust ◽

Rare Earth Element ◽

Lower Crust ◽

Sedimentary Rock ◽

Earth Element ◽

Upper Crust ◽

Crustal Composition ◽

Eu Anomaly

The composition of the present-day upper crust, inferred from the uniformity of sedimentary rock r.e.e. (rare earth element) patterns, is close to that of granodiorite. A revised ‘andesite’ model is used to obtain total crustal composition. The lower crust is the composition remaining, assuming that the upper crust, one-third of the total, is derived from intracrustal partial melting. The upper-crustal r.e.e. pattern has pronounced Eu depletion (Eu/Eu* = 0.64), the lower-crustal pattern has Eu enrichment (Eu/Eu* = 1.17) and the total crust has no Eu anomaly relative to chondritic abundances. The Eu depletion in the upper crust is attributed to retention of Eu in plagioclase in the lower crust. Because plagioclase is not stable below 40 km (> 10 kbar), the anomaly is intracrustal in origin. The Archaean upper crust has a different r.e.e. pattern to that of the present-day upper crust, being lower in total r.e.e., and La/Yb ratios, and lacking an Eu anomaly. These data are used to infer the Archaean upper-crustal composition, which resembles that of the present-day total crust, except that Ni and Cr contents are higher. The Archaean crustal composition can be modelled by a mixture of tholeiites and tonalite trondhjemites. The latter have steep light r.e.e.-enriched-heavy r.e.e.-depleted patterns, consistent with equilibration with garnet and hence probable mantle derivation. There is little reason to suppose that the Archaean lower crust was different in composition from the upper crust, except locally where partial melting episodes occurred. The r.e.e. evidence is consistent with isotopic and geological evidence for a low continental growth rate in the early Archaean, a massive increase (to about 70% of the total crust) between about 3000 and 2500 Ma B.P. and a slow increase until the present day. The change from Archaean to post-Archaean r.e.e. patterns in the upper crust is not isochronous, but is reflected in the sedimentary rock r.e.e. patterns at differing times in different continents. On the basis of a model composition for the mantle, 36% of the potassium, 30% of uranium, 15% of lanthanum and 3 % of ytterbium are concentrated in the present continental crust. This enrichment is related to ionic size and valency differences from common mantle cations (e.g. Mg, Fe). Pre-3.9 Ga B.P. crusts were obliterated by meteorite bombardment. No geochemical evidence exists for primordial anorthositic, sialic or mafic crusts.

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