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Cutts, Jamie Alistair (2019) Geochronology of ultrahigh-pressure rocks to interrogate the evolution of the continental crust and mantle. University of British Columbia. doi:10.14288/1.0378408

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Reference TypeJournal (article/letter/editorial)
TitleGeochronology of ultrahigh-pressure rocks to interrogate the evolution of the continental crust and mantle
JournalUniversity of British Columbia
AuthorsCutts, Jamie AlistairAuthor
Year2019
PublisherUniversity of British Columbia
URL
DOIdoi:10.14288/1.0378408Search in ResearchGate
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Original EntryCutts, J. A. (2019) Geochronology of ultrahigh-pressure rocks to interrogate the evolution of the continental crust and mantle. Thesis, University of British Columbia. Doi: 10.14288/1.0378408
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Mindat Ref. ID16083042Long-form Identifiermindat:1:5:16083042:8
GUID0
Full ReferenceCutts, Jamie Alistair (2019) Geochronology of ultrahigh-pressure rocks to interrogate the evolution of the continental crust and mantle. University of British Columbia. doi:10.14288/1.0378408
Plain TextCutts, Jamie Alistair (2019) Geochronology of ultrahigh-pressure rocks to interrogate the evolution of the continental crust and mantle. University of British Columbia. doi:10.14288/1.0378408
InLink this record to the correct parent record (if possible)
Abstract/NotesThe formation of cratonic lithosphere and its participation in continental collision are first-order processes in global tectonics. The Western Gneiss Complex (WGC) of southwestern Norway is a fragment of continental crust that uniquely preserves a complete record of its burial and exhumation during collisional orogeny along with rare fragments of sub-continental lithospheric mantle that were entrained into the terrane during its residence in the mantle. Despite the importance of the WGC for characterising processes operating in the deep crust and mantle during continent-continent collision, its rate and style of burial and exhumation have not been comprehensively studied and the protracted evolution of the included peridotite bodies remains unclear. Lu-Hf garnet and micro-analytical U-Pb rutile geochronology are two powerful tools for lithosphere and tectonics research as they can be used to link ages to conditions of equilibration of rock-forming assemblages. Using these techniques applied to eclogites in the WGC, I constrained the burial rate for continental crust during collisional orogeny to ~5 mm yr-¹, developed a quantitative framework for evaluating geodynamic changes during continental collision, and proposed that deeply buried continental crust is exhumed largely as a flat-slab in the mid-crust, possibly due to erosion of a paleo-plateau in the upper plate. Using Lu-Hf garnet geochronology applied to ultrahigh-pressure (UHP) enstatite-bearing eclogites in the WGC, I provided well-constrained empirical evidence for non-lithostatic eclogitisation, a process that explains the localised occurrence of anomalously-high pressures conditions in deeply buried continental crust. When these research outcomes are compared to the lower plate in the India-Asia collision zone, they demonstrate consistency in the rate and depth of burial and the style of exhumation of continental crust during collisional orogeny. Using Lu-Hf garnet geochronology applied to included peridotite bodies in the WGC, I provided the first well-constrained geochronological evidence for the stabilisation of a buoyant cratonic sub-continental lithospheric mantle in the Archean that melted and recrystallised in concert with major supercontinent break-up intervals. The techniques used herein could be applied to other collisional settings and to other mantle peridotite suites to better constrain the emergence and evolution of global plate tectonics cycles.

Map of Localities

Locality Pages

LocalityCitation Details
Bardane, Fjørtofta, Haram, Ålesund, Møre og Romsdal, Norway
Magerøy Eclogite, Korveneset, Otrøya, Midsund, Molde, Møre og Romsdal, Norway
Uglvik peridotite body, Uglvik, Otrøya, Midsund, Molde, Møre og Romsdal, Norway
Utsidevegen roadcut, Uglvik peridotite body, Uglvik, Otrøya, Midsund, Molde, Møre og Romsdal, Norway

Mineral Occurrences

LocalityMineral(s)
Bardane, Fjørtofta, Haram, Ålesund, Møre og Romsdal, Norway Chromium-bearing Diopside, Diopside, Enstatite, Phlogopite, Websterite
Magerøy Eclogite, Korveneset, Otrøya, Midsund, Molde, Møre og Romsdal, Norway Amphibole Supergroup, Clinopyroxene Subgroup, Eclogite, Garnet Group, Gneiss, Ilmenite, Orthopyroxene Subgroup, Pargasite, Phlogopite, Quartz, Rutile, Zircon
Utsidevegen roadcut, Uglvik peridotite body, Uglvik, Otrøya, Midsund, Molde, Møre og Romsdal, Norway Chromium-bearing Diopside, Diopside, Dunite, Enstatite, Forsterite, Pyrope, Serpentinite

See Also

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Macquistan, Mary Grace (2024) Paragenesis and evolution of Ba-silicate mineralization in Devonian strata at the Gun occurrence, the Yukon, Canada. University of British Columbia. doi:10.14288/1.0443092
Reinsbakken, Arne (1970) Detailed geological mapping and interpretation of the Grand Forks-Eholt area, Boundary District, British Columbia. Master of Science, University of British Columbia. 114 pp. doi:10.14288/1.0053174
Fagan, Andrew Jeffrey (2018) The ruby and pink sapphire deposits of SW Greenland : geological setting, genesis, and exploration techniques. University of British Columbia. doi:10.14288/1.0372956
Dalsin, M.L. (2013) The Mineralogy, Geochemistry and Geochronology of the Wicheeda Carbonatite Complex, British Columbia. M.Sc. Thesis, University of British Columbia, Vancouver.
Caudle, D. (2016) Mineralogy, geochemistry, and geochronology of the KIN property pegmatites in eastern British Columbia. Masters dissertation, University of British Columbia.
HIRAJIMA, Takao (1997) The Modern Metamorphic Petrology and Its Future. Transition from High-/ultrahigh-pressure Metamorphic Rocks to the Continental Crust. Journal of Geography (Chigaku Zasshi), 106 (5) 670-681 doi:10.5026/jgeography.106.5_670
Chopin, Christian (2003) Ultrahigh-pressure metamorphism: tracing continental crust into the mantle. Earth and Planetary Science Letters, 212 (1) 1-14 doi:10.1016/s0012-821x(03)00261-9
Li, Shuguang (1992) Sm/Nd evolution of upper mantle and continental crust: Constraints on growth rates of the continental crust. Chinese Journal of Geochemistry, 11 (4) 314-328 doi:10.1007/bf02869063
Ferrero, Silvio, Wunder, Bernd, Walczak, Katarzyna, O’Brien, Patrick J., Ziemann, Martin A. (2015) Preserved near ultrahigh-pressure melt from continental crust subducted to mantle depths. Geology, 43 (5) 447-450 doi:10.1130/g36534.1
Li, Zhonghai, Gerya, Taras V. (2009) Polyphase formation and exhumation of high- to ultrahigh-pressure rocks in continental subduction zone: Numerical modeling and application to the Sulu ultrahigh-pressure terrane in eastern China. Journal of Geophysical Research, 114. doi:10.1029/2008jb005935
Steinthorsdottir, Katrin, Dipple, Gregory M, Cutts, Jamie A, Turvey, Connor C, Milidragovic, Dejan, Peacock, Simon M (2022) Formation and Preservation of Brucite and Awaruite in Serpentinized and Tectonized Mantle in Central British Columbia: Implications for Carbon Mineralization and Nickel Mining. Journal of Petrology, 63 (11) doi:10.1093/petrology/egac100
 
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