Archaean basin margin geology and crustal evolution: an East Pilbara traverse

Nijman, Wouter; Kloppenburg, A.; Vries, Sjoukje T. de

doi:10.1144/jgs2016-127

Cited by 23 publications

(15 citation statements)

References 78 publications

(76 reference statements)

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“…19) are inconsistent with diapirism being the dominant doming process. Similar features have been documented in Archean granite-greenstone terranes, such as the Pilbara North Pole Dome in Australia (e.g., Nijman et al, 2017). Diapirism or crustal turnover has been proposed as a mechanism to explain these tonalite-trondhjemitegranodiorite (TTG)-cored domes (e.g., Collins et al, 1998), which are associated with larger melt fractions than Naxos migmatites.…”

Section: Partial Melting Decompression and Formation Of The Migmatite Domementioning

confidence: 55%

“…Diapirism or crustal turnover has been proposed as a mechanism to explain these tonalite-trondhjemitegranodiorite (TTG)-cored domes (e.g., Collins et al, 1998), which are associated with larger melt fractions than Naxos migmatites. The pattern of doming and basins with other observed shortening phenomena indicates the importance of regional compression during the formation of these domes, which may have caused a first Raleigh instability, leading to an egg-box pattern of sinking greenstones around the TTG domes (Nijman et al, 2017). N-S horizontal boudinage, and a range of brittle deformation features overprinting these folds, suggests the principal stress axes rotated to a NNE-SSWorientated σ 3 and E-W-oriented σ 1 direction shortly after these folds formed.…”

Section: Partial Melting Decompression and Formation Of The Migmatite Domementioning

confidence: 78%

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Compressional origin of the Naxos metamorphic core complex, Greece: Structure, petrography, and thermobarometry

et al. 2019

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The island of Naxos, Greece, has been previously considered to represent a Cordilleran-style metamorphic core complex that formed during Cenozoic extension of the Aegean Sea. Although lithospheric extension has undoubtedly occurred in the region since 10 Ma, the geodynamic history of older, regional-scale, kyanite- and sillimanite-grade metamorphic rocks exposed within the core of the Naxos dome is controversial. Specifically, little is known about the pre-extensional prograde evolution and the relative timing of peak metamorphism in relation to the onset of extension. In this work, new structural mapping is presented and integrated with petrographic analyses and phase equilibrium modeling of blueschists, kyanite gneisses, and anatectic sillimanite migmatites. The kyanite-sillimanite–grade rocks within the core complex record a complex history of burial and compression and did not form under crustal extension. Deformation and metamorphism were diachronous and advanced down the structural section, resulting in the juxtaposition of several distinct tectono-stratigraphic nappes that experienced contrasting metamorphic histories. The Cycladic Blueschists attained ∼14.5 kbar and 470 °C during attempted northeast-directed subduction of the continental margin. These were subsequently thrusted onto the more proximal continental margin, resulting in crustal thickening and regional metamorphism associated with kyanite-grade conditions of ∼10 kbar and 600–670 °C. With continued shortening, the deepest structural levels underwent kyanite-grade hydrous melting at ∼8–10 kbar and 680–750 °C, followed by isothermal decompression through the muscovite dehydration melting reaction to sillimanite-grade conditions of ∼5–6 kbar and 730 °C. This decompression process was associated with top-to-the-NNE shearing along passive-roof faults that formed because of SW-directed extrusion. These shear zones predated crustal extension, because they are folded around the migmatite dome and are crosscut by leucogranites and low-angle normal faults. The migmatite dome formed at lower-pressure conditions under horizontal constriction that caused vertical boudinage and upright isoclinal folds. The switch from compression to extension occurred immediately following doming and was associated with NNE-SSW horizontal boudinage and top-to-the-NNE brittle-ductile normal faults that truncate the internal shear zones and earlier collisional features. The Naxos metamorphic core complex is interpreted to have formed via crustal thickening, regional metamorphism, and partial melting in a compressional setting, here termed the Aegean orogeny, and it was exhumed from the midcrust due to the switch from compression to extension at ca. 15 Ma.

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Section: Partial Melting Decompression and Formation Of The Migmatite Domementioning

confidence: 55%

Section: Partial Melting Decompression and Formation Of The Migmatite Domementioning

confidence: 78%

Compressional origin of the Naxos metamorphic core complex, Greece: Structure, petrography, and thermobarometry

et al. 2019

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“…While no modern-style continental landmasses existed before 3.2 Ga, the preserved geological record from the Early Archaean (that can be translated probably back to the Hadean) documents small exposed landmasses on top of submerged ocean plateau-like protocontinents, something like volcanic Iceland surrounded by relatively protected collapse basins (cf. Nijman et al 2017). It is fair to say, however, that our current understanding or knowledge of any kind of exposed terrestrial surface during those early days is hazy (Sleep 2018).…”

Section: The Emergence Of Life: In the Oceans Or On Oceanic Edges?mentioning

confidence: 99%

The Emergence of Life

et al. 2019

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The aim of this article is to provide the reader with an overview of the different possible scenarios for the emergence of life, to critically assess them and, according to the conclusions we reach, to analyze whether similar processes could have been conducive to independent origins of life on the several icy moons of the Solar System. Instead of directly proposing a concrete and unequivocal cradle of life on Earth, we focus on describing the different requirements that are arguably needed for the transition between non-life to life. We Ocean Worlds Edited by 56 Page 2 of 53 E. Camprubí et al.approach this topic from geological, biological, and chemical perspectives with the aim of providing answers in an integrative manner. We reflect upon the most prominent origins hypotheses and assess whether they match the aforementioned abiogenic requirements. Based on the conclusions extracted, we address whether the conditions for abiogenesis are/were met in any of the oceanic icy moons.

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“…Such dome-and-keel structures ZHU ET AL. characterize the structural patterns of major Archean cratons, including the Barberton and Zimbabwe cratons in South Africa (Figure 3a; Anhaeusser & Wilson, 1981;Van Hinsbergen et al, 2011;Van Kranendonk et al, 2014), the Yilgara and Pilbara cratons in Western Australia (Figure 3b; Collins et al, 1998;Hallberg & Glikson, 1981;Nijman et al, 2017;Van Kranendonk et al, 2004), the Superior craton in North America (e.g., Lin, 2005;Lin & Beakhouse, 2013;, and the Eastern Block of the NCC in East Asia (Zhao, 2014;Zhao et al, 2001). In these old cratons, the boundaries between the gneiss domes and the supracrustals (greenstones) are characterized mostly by vertical stretching lineations or L-tectonites, indicating vertical motions (e.g., Lin, 2005;Lin & Beakhouse, 2013;.…”

Section: Structural Patterns Of Archean Cratonsmentioning

confidence: 99%

Origin, Accretion, and Reworking of Continents

Zhu

Zhao

Xiao

et al. 2021

Reviews of Geophysics

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Archean continental nuclei likely originated from oceanic plateaus formed by mantle plumes, not from island arcs via oceanic subduction Archean continental nuclei underwent accretion or growth at margins by oceanic subduction, involving juvenile arc formation and accretion Continental reworking occurs ubiquitously, with significant reworking/craton destruction being mainly associated with oceanic subduction Accepted ArticleThis article has been accepted for publication and undergone full peer review but has not been through the copyediting, typesetting, pagination and proofreading process, which may lead to differences between this version and the Version of Record. Please cite this article as

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Archaean basin margin geology and crustal evolution: an East Pilbara traverse

Cited by 23 publications

References 78 publications

Compressional origin of the Naxos metamorphic core complex, Greece: Structure, petrography, and thermobarometry

Compressional origin of the Naxos metamorphic core complex, Greece: Structure, petrography, and thermobarometry

The Emergence of Life

Origin, Accretion, and Reworking of Continents

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