Mineralogy and petrogenesis of pegmatites in the Spruce Pine District, North Carolina, USA

Swanson, Samuel E.; Veal, William Brian

doi:10.3190/jgeosci.062

Cited by 13 publications

(6 citation statements)

References 11 publications

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“…Moreover, these ages are consistent with the uranium mineralization associated with the pegmatite intrusion in the region at 1030-1070 Ma (Table 1) [35]. The calculated U-Pb and Pb-Pb dates for Yancey uraninite (Figure 4c,d, Table 3) corroborate both the reported Rb-Sr and U-Pb ages of 377-404 Ma for the pegmatite intrusions associated with the Spruce Pine Plutonic Suite (Table 1) [34]. The pristine aliquot for the Yancey uraninite yields a concordant calculated age of 374.1 ± 7.2 Ma, whereas, the altered aliquot shows U gain (Figure 4d, Table 3).…”

Section: Resultssupporting

confidence: 82%

“…Yancey is a Paleozoic pegmatite-hosted uraninite from the Spruce Pine pegmatite, Yancey County, North Carolina, which forms part of the Spruce Pine thrust block. The pegmatite crosscuts Precambrian interlayered mica and amphibole gneiss and schist of the Ashe Formation in the Blue Ridge of the Appalachian Mountains [33,34]. Dating of the Spruce Pine pegmatites has included whole rock Rb-Sr ages on two pegmatites with reported dates of 404 and 392 Ma, and U-Pb dating of zircons from the pluton yield a date of 377 Ma [34].…”

Section: Samples and Methodsmentioning

confidence: 99%

“…The pegmatite crosscuts Precambrian interlayered mica and amphibole gneiss and schist of the Ashe Formation in the Blue Ridge of the Appalachian Mountains [33,34]. Dating of the Spruce Pine pegmatites has included whole rock Rb-Sr ages on two pegmatites with reported dates of 404 and 392 Ma, and U-Pb dating of zircons from the pluton yield a date of 377 Ma [34]. The Bancroft and Cardiff samples are both from the Bancroft region of Ontario, Canada.…”

Section: Samples and Methodsmentioning

confidence: 99%

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Geochronology of Uraninite Revisited

Corcoran

Simonetti

2020

Minerals

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Identification of uraninite provenance for the purpose of nuclear forensics requires a multifaceted approach. Various geochemical signatures, such as chondrite normalized rare earth element patterns, help identify and limit the potential sources of uraninite based on the geological setting of the uranium ore mineralization. The inclusion of accurate age determinations to discriminate geochemical signatures for natural uranium ores may help to potentially restrict geographical areas for provenance consideration. Determining a robust age for uraninite formation is somewhat difficult, due to well known, inherent difficulties associated with open system behavior that involve either uranium and/or lead loss or gain. However, open system behavior should not perturb their Pb isotopic compositions to the same degree as Pb isotopes should not fractionate during alteration processes. Here, a suite of pristine and altered samples of uraninite was examined for their Pb isotope compositions, and these yielded geologically meaningful secondary Pb–Pb isochron ages. The degree of alteration within individual uraninite samples, which is extremely variable, does not appear to affect the calculated ages. The approach adopted here yields insightful age information, and hence, is of great value for source attribution in forensic analyses of raw nuclear materials.

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Section: Resultssupporting

confidence: 82%

Section: Samples and Methodsmentioning

confidence: 99%

Section: Samples and Methodsmentioning

confidence: 99%

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Geochronology of Uraninite Revisited

Corcoran

Simonetti

2020

Minerals

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“…The fact that this thermal event was weaker than the Salinic/Taconic metamorphism and was not accompanied by major deformation suggests that it may have been related to hydrothermal activity caused by the intrusion of magma (at depths >20 km), rather than by the major deformation recorded in the Inner Piedmont during this orogeny. This is consistent with the intrusion of granitoids such as the Yonah Mountain tonalite located 33 miles to the southwest of WSG and intruded at 346 ± 17 Ma (Mapes, 2002), or the Spruce Pine Pegmatites intruded at 7–11 kbar (Swanson & Veal, 2010) 361 ± 2 Ma (Mapes, 2002). Following this thermal event, the Cartoogechaye terrane continued to be exhumed as the Dahlonega Gold belt continued to be underthrust beneath it, possibly facilitated by the emplacement of the Tugaloo terrane (Hatcher et al.…”

Section: Tectonic Implicationssupporting

confidence: 67%

P-T-t evolution of granulite facies metamorphism and partial melting in the Winding Stair Gap, Central Blue Ridge, North Carolina, USA

El‐Shazly

Loehn

Tracy

2011

Journal of Metamorphic Geology

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The Winding Stair Gap in the Central Blue Ridge province exposes granulite facies schists, gneisses, granofelses and migmatites characterized by the mineral assemblages: garnet-biotite-sillimaniteplagioclase-quartz, garnet-hornblende-biotite-plagioclase-quartz ± orthopyroxene ± clinopyroxene and orthopyroxene-biotite-quartz. Multiple textural populations of biotite, kyanite and sillimanite in pelitic schists support a polymetamorphic history characterized by an early clockwise P-T path in which dehydration melting of muscovite took place in the stability field of kyanite. Continued heating led to dehydration melting of biotite until peak conditions of 850 ± 30°C, 9 ± 1 kbar were reached. After equilibrating at peak temperatures, the rocks underwent a stage of near isobaric cooling during which hydrous melt ± K-feldspar were replaced by muscovite, and garnet by sillimanite + biotite + plagioclase. Most monazite crystals from a pelitic schist display patchy zoning for Th, Y and U, with some matrix crystals having as many as five compositional zones. A few monazite inclusions in garnet, as well as Y-rich cores of some monazite matrix crystals, yield the oldest dates of c. 500 Ma, whereas a few homogeneous matrix monazites that grew in the main foliation plane yield dates of 370-330 Ma. Culling and analysis of individual spot dates for eight monazite grains yields three age populations of 509 ± 14 Ma, 438 ± 5 Ma and 360 ± 5 Ma. These data suggest that peak-temperature metamorphism and partial melting in the central Blue Ridge occurred during the Salinic or Taconic orogeny. Following near isobaric cooling, a second weaker thermal pulse possibly related to intrusion of nearby igneous bodies resulted in growth of monazite c. 360 Ma, coinciding with the Neoacadian orogeny.

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“…However, natural quartz deposits suitable for HPQ production are rare [1,4,6]. Specifically, the quartz crucibles and semiconductor base materials consumed in photovoltaic and integrated circuit industries have been depending on HPQ produced from the Spruce Pine mining area for a long time [3,7,8], posing serious risks for world HPQ supply chain.…”

Section: Introductionmentioning

confidence: 99%

Trace Element Concentrations and Mineralogy of Quartz Vein Deposits from Southeastern Hubei Province, China

et al. 2022

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Hydrothermal quartz samples collected from the Fujiashan and Yipanqiu quartz deposits in southeastern Hubei Province, China have been investigated by analytical combination of optical microscopy, scanning electron microscopy, and inductively coupled plasma optical emission spectroscopy, in conjunction with conventional beneficiation processing to evaluate their potential as sources of high purity quartz (HPQ) from a commercial perspective. Microscopy efforts reveal that major mineral impurities associated with quartz are K-feldspar, muscovite, iron oxides, rutile with accessory kaolinite. Bulk trace element concentrations of the processed quartz products demonstrate that the Fujiashan-II quartz vein with cumulative impurities of less than 50 μg g−1 with <30 μg g−1 Al and <10 μg g−1 Ti fits with the lattice-bound criteria for HPQ, meeting the requirement by a HPQ deposit. However, the Yipanqiu quartz deposits are not promising for HPQ production due to high fluid inclusion contents, intimate intergrowth texture with highly variable crystal size, and probably high lattice-bound element contents. The early Neoproterozoic Fujiashan quartz deposits have likely been experienced long-term retrograde metamorphism-related recrystallisation which might contribute to high-purity quartz formation. Due to a much younger crystallization age compared to the Fujiashan deposits, quartz grains in the middle Cretaceous Yipanqiu quartz vein retain high trace elements, leading to exclusion of being a HPQ deposit.

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Mineralogy and petrogenesis of pegmatites in the Spruce Pine District, North Carolina, USA

Cited by 13 publications

References 11 publications

Geochronology of Uraninite Revisited

Geochronology of Uraninite Revisited

P-T-t evolution of granulite facies metamorphism and partial melting in the Winding Stair Gap, Central Blue Ridge, North Carolina, USA

Trace Element Concentrations and Mineralogy of Quartz Vein Deposits from Southeastern Hubei Province, China

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