Evolution of mafic enclaves and their host calc-alkaline granite, South Sinai, Egypt

The Qingshanbao complex, part of the uranium metallogenic belt of the Longshou-Qilian mountains, is located in the center of the Longshou Mountain next to the Jiling complex that hosts a number of U deposits. However, little research has been conducted in this area. In order to investigate the origin and formation of mafic enclaves observed in the Qingshanbao body and the implications for magmatic-tectonic dynamics, we systematically studied the mineralogy, petrography, and geochemistry of these enclaves. Our results showed that the enclaves contain plagioclase enwrapped by early dark minerals. These enclaves also showed round quartz crystals and acicular apatite in association with the plagioclase. Electron probe analyses showed that the plagioclase in the host rocks (such as K-feldspar granite, adamellite, granodiorite, etc.) show normal zoning, while the plagioclase in the mafic enclaves has a discontinuous rim composition and shows instances of reverse zoning. Major elemental geochemistry revealed that the mafic enclaves belong to the calc-alkaline rocks that are rich in titanium, iron, aluminum, and depleted in silica, while the host rocks are calc-alkaline to alkaline rocks with enrichment in silica. On Harker diagrams, SiO2 contents are negatively correlated with all major oxides but K2O. Both the mafic enclaves and host rock are rich in large ion lithophile elements such as Rb and K, as well as elements such as La, Nd, and Sm, and relatively poor in high field strength elements such as Nb, Ta, P, Ti, and U. Element ratios of Nb/La, Rb/Sr, and Nb/Ta indicate that the mafic enclaves were formed by the mixing of mafic and felsic magma. In terms of rare earth elements, both the mafic enclaves and the host rock show right-inclined trends with similar weak to medium degrees of negative Eu anomaly and with no obvious Ce anomaly. Zircon LA-ICP-MS (Laser ablation inductively coupled plasma mass spectrometry) U-Pb concordant ages of the mafic enclaves and host rock were determined to be 431.8 5.2 Ma (MSWD (mean standard weighted deviation)= 1.5, n = 14) and 432.8 4.2 Ma (MSWD = 1.7, n = 16), respectively, consistent with that for the zircon U-Pb ages of the granite and medium-coarse grained K-feldspar granites of the Qingshanbao complex. The estimated ages coincide with the timing of the late Caledonian collision of the Alashan Block. This comprehensive analysis allowed us to conclude that the mafic enclaves in the Qingshanbao complex were formed by the mixing of crust-mantle magma with mantle-derived magma due to underplating, which caused partial melting of the ancient basement crust during the collisional orogenesis between the Alashan Block and Qilian rock mass in the early Silurian Period.

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Petrogenesis of a late-stage calc-alkaline granite in a giant S-type batholith: geochronology and Sr–Nd–Pb isotopes from the Nomatsaus granite (Donkerhoek batholith), Namibia

International Journal of Earth Sciences ◽

10.1007/s00531-021-02024-w ◽

2021 ◽

Author(s):

S. Aspiotis ◽

S. Jung ◽

F. Hauff ◽

R. L. Romer

Keyword(s):

Partial Melting ◽

Mineral Assemblage ◽

Central Zone ◽

Calc Alkaline ◽

Pb Isotope ◽

Alkaline Granite ◽

Ti Oxides ◽

Eu Anomaly ◽

Environment Characteristic ◽

Southern Central

AbstractThe late-tectonic 511.4 ± 0.6 Ma-old Nomatsaus intrusion (Donkerhoek batholith, Damara orogen, Namibia) consists of moderately peraluminous, magnesian, calc-alkalic to calcic granites similar to I-type granites worldwide. Major and trace-element variations and LREE and HREE concentrations in evolved rocks imply that the fractionated mineral assemblage includes biotite, Fe–Ti oxides, zircon, plagioclase and monazite. Increasing K2O abundance with increasing SiO2 suggests accumulation of K-feldspar; compatible with a small positive Eu anomaly in the most evolved rocks. In comparison with experimental data, the Nomatsaus granite was likely generated from meta-igneous sources of possibly dacitic composition that melted under water-undersaturated conditions (X H2O: 0.25–0.50) and at temperatures between 800 and 850 °C, compatible with the zircon and monazite saturation temperatures of 812 and 852 °C, respectively. The Nomatsaus granite has moderately radiogenic initial 87Sr/86Sr ratios (0.7067–0.7082), relatively radiogenic initial εNd values (− 2.9 to − 4.8) and moderately evolved Pb isotope ratios. Although initial Sr and Nd isotopic compositions of the granite do not vary with SiO2 or MgO contents, fSm/Nd and initial εNd values are negatively correlated indicating limited assimilation of crustal components during monazite-dominated fractional crystallization. The preferred petrogenetic model for the generation of the Nomatsaus granite involves a continent–continent collisional setting with stacking of crustal slices that in combination with high radioactive heat production rates heated the thickened crust, leading to the medium-P/high-T environment characteristic of the southern Central Zone of the Damara orogen. Such a setting promoted partial melting of metasedimentary sources during the initial stages of crustal heating, followed by the partial melting of meta-igneous rocks at mid-crustal levels at higher P–T conditions and relatively late in the orogenic evolution.

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Release of Uranium from Uraninite in Granites Through Alteration: Implications for the Source of Granite-Related Uranium Ores

Economic Geology ◽

10.5382/econgeo.4822 ◽

2021 ◽

Author(s):

Long Zhang ◽

Zhenyu Chen ◽

Fangyue Wang ◽

Noel C. White ◽

Taofa Zhou

Keyword(s):

Uranium Concentration ◽

Geochemical Data ◽

Uranium Deposits ◽

Bulk Rock ◽

Calc Alkaline ◽

Alkaline Granite ◽

Compositional Evolution ◽

High K ◽

Backscattered Electron ◽

Uranium Sources

Abstract Uraninite is the main contributor to the bulk-rock uranium concentration in many U-rich granites and is the most important uranium source for granite-related uranium deposits. However, detailed textural and compositional evolution of magmatic uraninite in granites during alteration and associated uranium mobilization have not been well documented. In this study, textures and geochemistry of uraninites from the Zhuguangshan batholith (South China) were investigated by scanning electron microscopy (SEM) and electron probe microanalysis (EPMA). The geochemical data indicate that the Longhuashan and Youdong plutons are peraluminous leucogranite, the Changjiang pluton is highly fractionated high-K calc-alkaline granite, and the Jiufeng pluton belongs to a high-K calc-alkaline association. Uraninites from the Longhuashan and Youdong granites have lower concentrations of ThO2 (0.9–4.0 wt %) and rare earth elements (REE)2O3 (0.1–1.0 wt %) than those from the Changjiang and Jiufeng granites (ThO2 = 4.4–7.6 wt %, REE2O3 = 0.7–5.1 wt %). Uraninites observed in the Longhuashan, Youdong, Changjiang, and Jiufeng granites yielded chemical ages of 223 ± 3, 222 ± 2, 157 ± 1, and 161 ± 2 Ma, respectively. The samples (including altered and unaltered) collected from the Longhuashan, Youdong, and Changjiang granites are characterized by highly variable whole-rock U concentrations of 6.9 to 44.7 ppm and Th/U ratios of 0.9 to 7.0, consistent with crystallization of uraninite in these granites being followed by uranium leaching during alteration. Alteration of uraninite, indicated by altered domains developing microcracks and appearing darker in backscattered electron (BSE) images compared to unaltered domains, results in the incorporation of Si and Ca and mobilization of U. In contrast, the least altered samples of the unmineralized Jiufeng granite have low U concentrations (5.3–16.4 ppm) and high ΣREE/U (13.6–49.4) and Th/U ratios (2.1–5.6), which inhibit crystallization of uraninite, as its crystallization occurs when the U concentration is high enough to exceed the substitution capacity of other U-bearing minerals. These results indicate that the Longhuashan, Youdong, and Changjiang granites were favorable uranium sources for the formation of uranium deposits in this area. This study highlights the potential of uraninite alteration and geochemistry to assist in deciphering uranium sources and enrichment processes of granite-related uranium deposits.

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Petrogenesis of two granites from the Nilgiri and Madurai blocks, southwestern India: Implications for charnockite–calc-alkaline granite and charnockite–alkali (A-type) granite link in high-grade terrains

Precambrian Research ◽

10.1016/j.precamres.2007.07.023 ◽

2008 ◽

Vol 162 (1-2) ◽

pp. 180-197 ◽

Cited By ~ 16

Author(s):

H RAJESH

Keyword(s):

High Grade ◽

Calc Alkaline ◽

Alkaline Granite ◽

Type Granite ◽

Southwestern India

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Uranium and selected trace elements in granites from the Caledonides of East Greenland

Mineralogical Magazine ◽

10.1180/minmag.1982.046.339.06 ◽

1982 ◽

Vol 46 (339) ◽

pp. 201-210 ◽

Cited By ~ 6

Author(s):

Agnete Steenfelt

Keyword(s):

Trace Elements ◽

Heat Source ◽

Iron Oxides ◽

Hydrothermal Fluids ◽

Fold Belt ◽

Calc Alkaline ◽

Alkaline Granite ◽

Acid Magma ◽

East Greenland ◽

Secondary Enrichment

AbstractThe Caledonian fold belt of East Greenland contains calc-alkaline granite (sensu lato) intrusions with ages ranging from c.2000 Ma to c.350 Ma. The Proterozoic granites have low U contents and the pre-Devonian Caledonian granites contents of U corresponding to the clarke value for U in granites. Some aspects of the geochemistry of U are discussed using U-K/Rb, U-Sr, U-Zr, and U-Th diagrams. Secondary enrichment and mineralization occurs in fractured and hydrothermally altered granites and rhyolites situated in or near a major NNE fault zone. The U is associated with iron oxides or hydrocarbons. It is suggested that the source of the mineralization was Devonian acid magma, which also acted as a heat source for circulating hydrothermal fluids.

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Hybridization of shoshonitic lamprophyre and calc‐alkaline granite magma in the early Proterozoic Mt Bundey igneous suite, Northern Territory

Australian Journal of Earth Sciences ◽

10.1080/08120099508728190 ◽

1995 ◽

Vol 42 (2) ◽

pp. 173-185 ◽

Cited By ~ 21

Author(s):

S. Sheppard

Keyword(s):

Northern Territory ◽

Calc Alkaline ◽

Alkaline Granite ◽

Granite Magma ◽

Early Proterozoic

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Mixing of cogenetic magmas in the Cretaceous Zhangzhou calc-alkaline granite from SE China recorded by in-situ apatite geochemistry

American Mineralogist ◽

10.2138/am-2021-7786 ◽

2021 ◽

Keyword(s):

Calc Alkaline ◽

Alkaline Granite ◽

Se China

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Mafic enclaves in the Wilson Ridge Pluton, northwestern Arizona: Implications for the generation of a calc-alkaline intermediate pluton in an extensional environment

Journal of Geophysical Research Atmospheres ◽

10.1029/jb095ib11p17693 ◽

1990 ◽

Vol 95 (B11) ◽

pp. 17693 ◽

Cited By ~ 18

Author(s):

Lance L. Larsen ◽

Eugene I. Smith

Keyword(s):

Calc Alkaline ◽

Mafic Enclaves

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Igneous banding, schlieren and mafic enclaves in calc-alkaline granites: The Budduso pluton (Sardinia)

Lithos ◽

10.1016/j.lithos.2007.12.004 ◽

2008 ◽

Vol 104 (1-4) ◽

pp. 147-163 ◽

Cited By ~ 42

Author(s):

P. Barbey ◽

D. Gasquet ◽

C. Pin ◽

A.L. Bourgeix

Keyword(s):

Calc Alkaline ◽

Mafic Enclaves

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Geochemistry and geochronology of the gneisses east of the Southern Rocky Mountain Trench, near Valemount, British Columbia

Canadian Journal of Earth Sciences ◽

10.1139/e85-103 ◽

1985 ◽

Vol 22 (7) ◽

pp. 980-991

Author(s):

V. E. Chamberlain ◽

R. St J. Lambert ◽

J. G. Holland

Keyword(s):

Rocky Mountain ◽

Tholeiitic Basalt ◽

Geochemical Data ◽

Geological History ◽

Calc Alkaline ◽

Geochronological Data ◽

Alkaline Granite ◽

Facies Metamorphism ◽

Major Fault ◽

Southern Rocky Mountain

Petrographic, geochemical, and geochronological data are presented on the gneisses of the Bulldog Creek block, the Mount Blackman block, and the Hugh Allan Creek block, which lie to the east of the Southern Rocky Mountain Trench (SRMT) south of Valemount, British Columbia.Petrographical and geochemical data, especially immobile-trace-element ratios (Nb: Y, Ti: Zr), and CaO versus Y and AFM plots are used to deduce the probable origins and protoliths of the gneisses. The Mount Blackman block consists of a psammitic paragneiss, probably derived from an immature arkosic sedimentary protolith, intruded by sills of tholeiitic basalt, now amphibolites. The Bulldog Creek block consists of felsic orthogneisses of calc-alkaline affinity, which are structurally concordant with mafic orthogneisses of possible tholeiitic basalt parentage. The Hugh Allan Creek block consists of a felsic orthogneiss with a probable alkaline granite protolith.Rb–Sr, and some U–Pb analyses show that each block has experienced a separate geological history. The Mount Blackman block psammitic paragneisses are the only analysed gneisses east of SRMT with a probable Archean Rb–Sr model crustal residence age. U–Pb analyses on zircons from these gneisses give a 1950 Ma minimum source rock age, and Rb–Sr whole-rock analyses suggest a 1860 ± 50 Ma age for amphibolite-facies metamorphism of both paragneisses and amphibolites. The Bulldog Creek block gneisses have a metamorphic age of at least 640 Ma, but their Rb–Sr systematics have been extensively disturbed, possibly during Mesozoic retrogressive metamorphism. The Hugh Allan Creek block gneisses have a Rb–Sr model crustal residence age of ~900 Ma and a metamorphic age of 805 ± 11 Ma. It is not possible to correlate any of these lithologies or events across the SRMT with the Malton block, and it is concluded that the SRMT is the site of a major fault or faults at this latitude.

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