P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia
The ~ 120,000 km2 Musgrave Province forms part of a continuous Musgrave–Albany–Fraser mid-late Mesoproterozoic orogenic system that transects central and southern Australia, and continues into formerly contiguous Antarctica. Voluminous felsic magmatic rocks that intruded over the interval 1330–1150...
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ftcurtin:oai:espace.curtin.edu.au:20.500.11937/7774 2023-06-11T04:04:17+02:00 P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia Walsh, A. Kelsey, D. Kirkland, Chris Hand, M. Smithies, R. Clark, Chris Howard, H. 2015 restricted https://hdl.handle.net/20.500.11937/7774 https://doi.org/10.1016/j.gr.2014.05.012 unknown Elsevier Inc. http://hdl.handle.net/20.500.11937/7774 doi:10.1016/j.gr.2014.05.012 Journal Article 2015 ftcurtin https://doi.org/20.500.11937/777410.1016/j.gr.2014.05.012 2023-05-30T19:23:55Z The ~ 120,000 km2 Musgrave Province forms part of a continuous Musgrave–Albany–Fraser mid-late Mesoproterozoic orogenic system that transects central and southern Australia, and continues into formerly contiguous Antarctica. Voluminous felsic magmatic rocks that intruded over the interval 1330–1150 Ma, corresponding globally to the Grenvillian timeline, dominate the Musgrave Province. However, rare but widely distributed metapelitic granulites contain peak metamorphic mineral assemblages comprising garnet + sillimanite ± quartz ± spinel. These are variably overprinted by coronae and/or symplectites of cordierite-bearing assemblages such as cordierite + spinel + magnetite ± plagioclase ± garnet. Petrologic forward modelling and Zr-in-rutile thermometry indicates these peak mineral assemblages developed at thermally extreme conditions of approximately 1000 °C and ca. 7–8 kbar. These ultra-high temperature (UHT) conditions appear to have prevailed throughout the Musgrave Province, across an approximate 600 km strike distance. The retrograde P–T evolution was characterised by modest decreases in pressure during the initial high temperature segment of the cooling path, suggesting that the crust was not significantly thickened as a result of tectonism. Combined SIMS (SHRIMP) and LA–ICP–MS U–Pb geochronology constrains the total range of metamorphic monazite growth/recrystallisation ages span 1263–1111 Ma with most individual samples spanning an age range of ≥ 80 Myr. The total age span implies approximately 150 Myr of perturbed thermal conditions during the Musgrave Orogeny. Our data requires that monazite is extremely resistive to isotopic resetting, even when exposed to extreme thermal conditions for long (≥ 80 Myr) periods. The thermal conditions, large regional footprint and long timescale of metamorphism and magmatism classify the Musgrave Province as a large, hot orogen. Article in Journal/Newspaper Antarc* Antarctica Curtin University: espace Gondwana Research 28 2 531 564 |
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Open Polar |
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Curtin University: espace |
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ftcurtin |
language |
unknown |
description |
The ~ 120,000 km2 Musgrave Province forms part of a continuous Musgrave–Albany–Fraser mid-late Mesoproterozoic orogenic system that transects central and southern Australia, and continues into formerly contiguous Antarctica. Voluminous felsic magmatic rocks that intruded over the interval 1330–1150 Ma, corresponding globally to the Grenvillian timeline, dominate the Musgrave Province. However, rare but widely distributed metapelitic granulites contain peak metamorphic mineral assemblages comprising garnet + sillimanite ± quartz ± spinel. These are variably overprinted by coronae and/or symplectites of cordierite-bearing assemblages such as cordierite + spinel + magnetite ± plagioclase ± garnet. Petrologic forward modelling and Zr-in-rutile thermometry indicates these peak mineral assemblages developed at thermally extreme conditions of approximately 1000 °C and ca. 7–8 kbar. These ultra-high temperature (UHT) conditions appear to have prevailed throughout the Musgrave Province, across an approximate 600 km strike distance. The retrograde P–T evolution was characterised by modest decreases in pressure during the initial high temperature segment of the cooling path, suggesting that the crust was not significantly thickened as a result of tectonism. Combined SIMS (SHRIMP) and LA–ICP–MS U–Pb geochronology constrains the total range of metamorphic monazite growth/recrystallisation ages span 1263–1111 Ma with most individual samples spanning an age range of ≥ 80 Myr. The total age span implies approximately 150 Myr of perturbed thermal conditions during the Musgrave Orogeny. Our data requires that monazite is extremely resistive to isotopic resetting, even when exposed to extreme thermal conditions for long (≥ 80 Myr) periods. The thermal conditions, large regional footprint and long timescale of metamorphism and magmatism classify the Musgrave Province as a large, hot orogen. |
format |
Article in Journal/Newspaper |
author |
Walsh, A. Kelsey, D. Kirkland, Chris Hand, M. Smithies, R. Clark, Chris Howard, H. |
spellingShingle |
Walsh, A. Kelsey, D. Kirkland, Chris Hand, M. Smithies, R. Clark, Chris Howard, H. P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia |
author_facet |
Walsh, A. Kelsey, D. Kirkland, Chris Hand, M. Smithies, R. Clark, Chris Howard, H. |
author_sort |
Walsh, A. |
title |
P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia |
title_short |
P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia |
title_full |
P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia |
title_fullStr |
P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia |
title_full_unstemmed |
P-T-t evolution of a large, long-lived, ultrahigh-temperature Grenvillian belt in central Australia |
title_sort |
p-t-t evolution of a large, long-lived, ultrahigh-temperature grenvillian belt in central australia |
publisher |
Elsevier Inc. |
publishDate |
2015 |
url |
https://hdl.handle.net/20.500.11937/7774 https://doi.org/10.1016/j.gr.2014.05.012 |
genre |
Antarc* Antarctica |
genre_facet |
Antarc* Antarctica |
op_relation |
http://hdl.handle.net/20.500.11937/7774 doi:10.1016/j.gr.2014.05.012 |
op_doi |
https://doi.org/20.500.11937/777410.1016/j.gr.2014.05.012 |
container_title |
Gondwana Research |
container_volume |
28 |
container_issue |
2 |
container_start_page |
531 |
op_container_end_page |
564 |
_version_ |
1768386783738855424 |