Trace element geochemistry of zircons frim in situ ocean lithoshere
Cobertura |
MEDIAN LATITUDE: 9.061589 * MEDIAN LONGITUDE: -13.808390 * SOUTH-BOUND LATITUDE: -33.250000 * WEST-BOUND LONGITUDE: -46.903610 * NORTH-BOUND LATITUDE: 30.168658 * EAST-BOUND LONGITUDE: 57.277530 * DATE/TIME START: 1987-12-06T04:45:00 * DATE/TIME END: 2004-12-07T19:57:00 |
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Data(s) |
15/12/2010
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Resumo |
We characterize the textural and geochemical features of ocean crustal zircon recovered from plagiogranite, evolved gabbro, and metamorphosed ultramafic host-rocks collected along present-day slow and ultraslow spreading mid-ocean ridges (MORs). The geochemistry of 267 zircon grains was measured by sensitive high-resolution ion microprobe-reverse geometry at the USGS-Stanford Ion Microprobe facility. Three types of zircon are recognized based on texture and geochemistry. Most ocean crustal zircons resemble young magmatic zircon from other crustal settings, occurring as pristine, colorless euhedral (Type 1) or subhedral to anhedral (Type 2) grains. In these grains, Hf and most trace elements vary systematically with Ti, typically becoming enriched with falling Ti-in-zircon temperature. Ti-in-zircon temperatures range from 1,040 to 660°C (corrected for a TiO2 ~ 0.7, a SiO2 ~ 1.0, pressure ~ 2 kbar); intra-sample variation is typically ~60-15°C. Decreasing Ti correlates with enrichment in Hf to ~2 wt%, while additional Hf-enrichment occurs at relatively constant temperature. Trends between Ti and U, Y, REE, and Eu/Eu* exhibit a similar inflection, which may denote the onset of eutectic crystallization; the inflection is well-defined by zircons from plagiogranite and implies solidus temperatures of ~680-740°C. A third type of zircon is defined as being porous and colored with chaotic CL zoning, and occurs in ~25% of rock samples studied. These features, along with high measured La, Cl, S, Ca, and Fe, and low (Sm/La)N ratios are suggestive of interaction with aqueous fluids. Non-porous, luminescent CL overgrowth rims on porous grains record uniform temperatures averaging 615 ± 26°C (2SD, n = 7), implying zircon formation below the wet-granite solidus and under water-saturated conditions. Zircon geochemistry reflects, in part, source region; elevated HREE coupled with low U concentrations allow effective discrimination of ~80% of zircon formed at modern MORs from zircon in continental crust. The geochemistry and textural observations reported here serve as an important database for comparison with detrital, xenocrystic, and metamorphosed mafic rock-hosted zircon populations to evaluate provenance. |
Formato |
application/zip, 3 datasets |
Identificador |
https://doi.pangaea.de/10.1594/PANGAEA.772872 doi:10.1594/PANGAEA.772872 |
Idioma(s) |
en |
Publicador |
PANGAEA |
Direitos |
CC-BY: Creative Commons Attribution 3.0 Unported Access constraints: unrestricted |
Fonte |
Supplement to: Grimes, Craig B; John, Barbara E; Cheadle, Michael J; Mazdab, Frank K; Wooden, Joseph L; Swapp, Susan; Schwartz, Joshua J (2009): On the occurrence, trace element geochemistry, and crystallization history of zircon from in situ ocean lithosphere. Contributions to Mineralogy and Petrology, 158(6), 757-783, doi:10.1007/s00410-009-0409-2 |
Palavras-Chave | #118-735B; 176-735B; 179-1105A; 209-1270D; 209-1275D; 304-U1309B; 304-U1309D; 305-U1309D; Al; Aluminium; Atlantic; Atlantis_Bank; Ca2+; Calcium; Calculated; Ce; Ce/Ce*; Ce-anomaly calculated in the following manner using chondrite-normalized values: Ce/Ce* = CeN/(square-root(LaN*PrN)). For samples in which Pr was not measured directly, chondrite normalized Pr values were estimated from smooth chondrite normalized REE patterns: Prest = LaN*(1/3) + NdN*(2/3)). An overestimate of La in zircon will therefore lead to overestimated Pr values. Normalizing values were from Korotev, 1996.; Cerium; Cerium anomaly; Chlorine; Cl; Comment; Corrected Ti-in-zircon temperature (after Ferry and Watson, 2007) assuming TiO2 activity = 0.7, SiO2 activity = 1, pressure =2 kbars; Depth; DEPTH, sediment/rock; Description; Dredge; DRG; DRILL; Drilling/drill rig; Dy; Dysprosium; Er; Erbium; Eu; Eu/Eu*; Eu-anomalies were calculated in the following manner using chondrite-normalized values: Eu/Eu* = EuN/(square-root(GdN*SmN)); Europium; Europium anomaly; Event; Exp304; Exp305; F; Fe; Fluorine; Gadolinium; Gd; Hafnium; Hf; Ho; Holmium; Indian Ocean; Integrated Ocean Drilling Program / International Ocean Discovery Program; IODP; IRD-Counting (Grobe, 1987); Iron; Joides Resolution; Kn180-2_09DRG; Kn180-2_11DRG; Kn180-2_25DRG; Knorr; KNR180-2; KNR180-2_112ROV_93; KNR180-2_117ROV_27; La; Label; Label 2; Lanthanum; Leg118; Leg176; Leg179; Leg209; Lu; Lutetium; Marvel2000; MULT; Multiple investigations; N; Nb; Nd; Neodymium; Niobium; North Atlantic; North Atlantic Ocean; Ocean Drilling Program; Oceanic Core Complex Formation, Atlantis Massive 1; Oceanic Core Complex Formation, Atlantis Massive 2; ODP; ODP sample designation; P; Phosphorus; Pr; Praseodymium; Remote operated vehicle; ROV; S; Samarium; Samp com; Sample amount; Sample code/label; Sample code/label 2; Sample comment; Sc; Scandium; Sensitive high-resolution ion microprobe-reverse geometry (SHRIMP-RG); Sm; South Indian Ridge, South Indian Ocean; spot; Sulfur; Tb; T cal; Temperature, calculated; Terbium; Th; Thorium; Thulium; Ti; Titanium; Tm; U; Uncorrected Ti-in-zircon temperature calculated using the equation of Ferry and Watson (2007) (Ti and Si activities = 1); Uranium; Y; Yb; Ytterbium; Yttrium |
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