Prolonged (&gt;100 Ma) ultrahigh temperature metamorphism in the Napier Complex, East Antarctica: A petrochronological investigation of Earth's hottest crust

Clark, Chris; Taylor, Richard; Kylander‐Clark, Andrew; Hacker, Bradley R.

doi:10.1111/jmg.12430

Cited by 46 publications

(29 citation statements)

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“…Such prolonged metamorphism is increasingly being recognized in the geological record through careful interpretation of coupled U-Pb and trace element data (e.g. Kelly and Harley, 2005;Korhonen et al, 2013;Clark et al, 2015Clark et al, , 2018Harley, 2016;Taylor et al, 2016;Cavalcante et al, 2018). The extremely slow rate of cooling implied by our data have implications for mechanisms of heat loss, and require that the lower crust remained melt present and close to isostatic equilibrium for more than 200 Myr.…”

Section: The Nature Of Archean Lower Crustmentioning

confidence: 68%

“…For example, continental crust subducted to ultrahigh pressure during collisional orogenesis is generally exhumed rapidly and cools fast (Hermann et al, 2001;Rubatto and Hermann, 2001;. By contrast, cooling of some granulite terranes may be slow (< or <<5 C/Myr) and close-to-isobaric (Harley, 1985;Harley and Black, 1987;Harley, 1989;Mezger et al, 1991;Ashwal et al, 1999;Möller et al, 2000;Vry and Baker, 2006;Korhonen et al, 2013;Clark et al, 2018;Mitchell et al, 2019), implying formation near the base of continental crust that was never significantly overthickened and which experienced sustained high mantle heat flow (Sandiford and Powell, 1986;Bohlen, 1991).…”

Section: Introductionmentioning

confidence: 99%

“…In addition, Archean granulite terrains commonly record a complex polyphase tectonothermal history that may obscure their early evolution (e.g. Clark et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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Persistence of melt-bearing Archean lower crust for >200 m.y.—An example from the Lewisian Complex, northwest Scotland

Taylor

Johnson

Clark

et al. 2019

Geology

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Geochronological data from zircon in Archean tonalite–trondhjemite–granodiorite (TTG) gneisses are commonly difficult to interpret. A notable example is the TTG gneisses from the Lewisian Gneiss Complex, northwest Scotland, which have metamorphic zircon ages that define a more-or-less continuous spread through the Neoarchean, with no clear relationship to zircon textures. These data are generally interpreted to record discrete high-grade events at ca. 2.7 Ga and ca. 2.5 Ga, with intermediate ages reflecting variable Pb loss. Although ancient diffusion of Pb is commonly invoked to explain such protracted age spreads, trace-element data in zircon may permit identification of otherwise cryptic magmatic and metamorphic episodes. Although zircons from the TTG gneiss analyzed here show a characteristic spread of Neoarchean ages, they exhibit subtle but key step changes in trace-element compositions that are difficult to ascribe to diffusive resetting, but that are consistent with emplacement of regionally extensive bodies of mafic magma. These data suggest suprasolidus metamorphic temperatures persisted for 200 m.y. or more during the Neoarchean. Such long-lived high-grade metamorphism is supported by data from zircon grains from a nearby monzogranite sheet. These preserve distinctive trace-element compositions consistent with derivation from a mafic source, and they define a well-constrained U-Pb zircon age of ca. 2.6 Ga that is intermediate between the two previously proposed discrete metamorphic episodes. The persistence of melt-bearing lower crust for hundreds of millions of years was probably the norm during the Archean.

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Section: The Nature Of Archean Lower Crustmentioning

confidence: 68%

Section: Introductionmentioning

confidence: 99%

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Persistence of melt-bearing Archean lower crust for >200 m.y.—An example from the Lewisian Complex, northwest Scotland

Taylor

Johnson

Clark

et al. 2019

Geology

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“…In this case the ‘rim’ specifically refers to garnet in contact with the quartz‐cordierite symplectite. These array plot parameters are key for identifying partitioning of REE between zircon and garnet during metamorphic events (Clark, Taylor, Kylander‐Clark, & Hacker, ; Taylor et al, , ). As can be seen in Figure , when the zircon grains are plotted against the garnet core they are offset from the experimental data set of Taylor et al (); however, when plotted against the garnet rim they fall closer to the experimental values.…”

Section: Discussionmentioning

confidence: 99%

Testing the fidelity of thermometers at ultrahigh temperatures

Clark

Taylor

Johnson

et al. 2019

Journal Metamorphic Geology

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A highly residual granulite facies rock (sample RG07‐21) from Lunnyj Island in the Rauer Group, East Antarctica, presents an opportunity to compare different approaches to constraining peak temperature in high‐grade metamorphic rocks. Sample RG07‐21 is a coarse‐grained pelitic migmatite composed of abundant garnet and orthopyroxene along with quartz, biotite, cordierite, and plagioclase with accessory rutile, ilmenite, zircon, and monazite. The inferred sequence of mineral growth is consistent with a clockwise pressure–temperature (P–T) evolution when compared with a forward model (P–T pseudosection) for the whole‐rock chemical composition. Peak metamorphic conditions are estimated at 9 ± 0.5 kbar and 910 ± 50°C based on conventional Al‐in‐orthopyroxene thermobarometry, Zr‐in‐rutile thermometry, and calculated compositional isopleths. U–Pb ages from zircon rims and neocrystallized monazite grains yield ages of c. 514 Ma, suggesting that crystallization of both minerals occurred towards the end of the youngest pervasive metamorphic episode in the region known as the Prydz Tectonic Event. The rare earth element compositions of zircon and garnet are consistent with equilibrium growth of these minerals in the presence of melt. When comparing the thermometry methods used in this study, it is apparent that the Al‐in‐orthopyroxene thermobarometer provides the most reliable estimate of peak conditions. There is a strong textural correlation between the temperatures obtained using the Zr‐in‐rutile thermometer––maximum temperatures are recorded by a single rutile grain included within orthopyroxene, whereas other grains included in garnet, orthopyroxene, quartz, and biotite yield a range of temperatures down to 820°C. Ti‐in‐zircon thermometry returns significantly lower temperature estimates of 678–841°C. Estimates at the upper end of this range are consistent with growth of zircon from crystallizing melt at temperatures close to the elevated (H2O undersaturated) solidus. Those estimates, significantly lower than the calculated temperature of this residual solidus, may reflect isolation of rutile from the effective equilibration volume leading to an activity of TiO2 that is lower than the assumed value of unity.

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“…The thermal history of the Napier Complex is important for unraveling the Earth's crustal evolution, including deep crust; however, geochronological constraints, such as the timing and duration of the metamorphic events, are still debated. Two hypotheses for the timing are proposed in previous studies: (i) the UHT metamorphism occurred no earlier than 2840 Ma and possibly from 2590 to 2550 Ma [4][5][6][7][8], (ii) it occurred from around 2500 to 2450 Ma [9][10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Geochemical Characterization of Zircon in Fyfe Hills of the Napier Complex, East Antarctica

2020

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Ultra-high temperature (UHT) metamorphism plays an essential role in the development and stabilization of continents through accretionary and collisional orogenesis. The Napier Complex, East Antarctica, preserves UHT metamorphism, and the timing is still debated. U–Pb zircon geochronology integrated with rare earth element (REE) and oxygen isotope was applied to a garnet-bearing quartzo-feldspathic gneiss to confirm the timing of UHT metamorphism in Fyfe Hills in the western part of the Napier Complex. The zircons are analyzed using a sensitive high-resolution ion microprobe (SHRIMP). The cathodoluminescence observation and U–Pb ages allowed us to classify the analytical domains into three types: inherited domains (Group I), metamorphic domains (Group II), and U–Pb system disturbed domains (Group III). The REE patterns of Group II are characterized by a weak fractionation between the middle REE and heavy REE, which reinforces the above classification. The 207Pb*/206Pb* ages of Group II have an age peak at 2501 Ma, therefore, the gneiss experienced high temperature metamorphism at 2501 Ma. δ18O of zircons are homogeneous among the three groups (5.53 ± 0.11‰, 5.51 ± 0.14‰, and 5.53 ± 0.23‰), which suggests re-equilibration of oxygen isotopes after metamorphism at ca. 2501Ma under dry UHT conditions.

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Prolonged (>100 Ma) ultrahigh temperature metamorphism in the Napier Complex, East Antarctica: A petrochronological investigation of Earth's hottest crust

Cited by 46 publications

References 93 publications

Persistence of melt-bearing Archean lower crust for >200 m.y.—An example from the Lewisian Complex, northwest Scotland

Persistence of melt-bearing Archean lower crust for >200 m.y.—An example from the Lewisian Complex, northwest Scotland

Testing the fidelity of thermometers at ultrahigh temperatures

Geochemical Characterization of Zircon in Fyfe Hills of the Napier Complex, East Antarctica

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Prolonged (>100 Ma) ultrahigh temperature metamorphism in the Napier Complex, East Antarctica: A petrochronological investigation of Earth's hottest crust

Cited by 46 publications

References 93 publications

Persistence of melt-bearing Archean lower crust for &gt;200 m.y.—An example from the Lewisian Complex, northwest Scotland

Persistence of melt-bearing Archean lower crust for &gt;200 m.y.—An example from the Lewisian Complex, northwest Scotland

Testing the fidelity of thermometers at ultrahigh temperatures

Geochemical Characterization of Zircon in Fyfe Hills of the Napier Complex, East Antarctica

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Product

Resources

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Persistence of melt-bearing Archean lower crust for >200 m.y.—An example from the Lewisian Complex, northwest Scotland

Persistence of melt-bearing Archean lower crust for >200 m.y.—An example from the Lewisian Complex, northwest Scotland