A reconstruction of the Eurekan Orogeny incorporating deformation constraints

Gion, Austin M.; Williams, S.; Müller, R. Dietmar

doi:10.1002/2015tc004094

Cited by 39 publications

(31 citation statements)

References 104 publications

(309 reference statements)

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“…Finally, the Paleocene age group indicates a rapid exhumation pulse at a rate of ≥0.4 km/Myr prior to sediment deposition. We interpret this rapid exhumation as reflecting a generally extensional period related to crustal thinning and tectonic denudation rather than tectonic uplift, because (i) it is coeval with basin formation and deposition in a coastal marine environment (as indicated by the palynology data) and, thus, with subsidence of parts of the continental margin, and (ii) it coincides with a period of crustal extension from Late Cretaceous‐Cenozoic times proposed by interpretation of aeromagnetic and gravity data for the northeastern Canadian Arctic margin (Anudu et al, ) and also predicted between 63 and 55 Ma by GPlates modeling (Gion et al, ; Harrison, ). Crustal thinning may have caused transtensional reactivation of preexisting fault zones, locally leading to pull‐apart(?)…”

Section: Discussionmentioning

confidence: 76%

“…Assuming geothermal gradients between 20 and 40 °C/km, average denudation rates for the lag time can be estimated between 0.85 and 0.25 km/Myr. Since denudation was presumably related to crustal extension/transtension (Harrison, ; Anudu et al, ; Gion et al, ; see also discussion on the pre‐Eurekan evolution), we consider a higher geothermal gradient to be more realistic and thus estimate denudation rates of ~0.45 to 0.25 km/Myr for the Paleocene, pre‐Eurekan stage, that is, for the time between isotopic closure (~63 Ma) and sediment deposition (~56 Ma). The increasing lag time and decreasing cooling rates from early to late Paleocene argue for an episodic high exhumation pulse during the Early Paleocene.…”

Section: Results and Interpretationmentioning

confidence: 99%

“…The Canadian Arctic must have experienced significant (trans)extension from the Late Cretaceous till at least the end of the Paleocene, as suggested by interpretations of structural data along the Nares Strait (Piepjohn et al, ) and of potential field data from the westernmost Ellesmere and Axel Heiberg islands (Anudu et al, ). An extensional regime in the Paleocene has also been assumed for a GPlates model (Gion et al, ), providing reconstructions with an estimated value of ~85 km of extension between Ellesmere and Devon Islands and of ~20 km of extension between Ellesmere and Axel Heiberg Islands (Harrison, ).…”

Section: Geological Settingmentioning

confidence: 99%

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Exhuming the Top End of North America: Episodic Evolution of the Eurekan Belt and Its Potential Relationships to North Atlantic Plate Tectonics and Arctic Climate Change

et al. 2019

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Section: Discussionmentioning

confidence: 76%

Section: Results and Interpretationmentioning

confidence: 99%

Section: Geological Settingmentioning

confidence: 99%

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Exhuming the Top End of North America: Episodic Evolution of the Eurekan Belt and Its Potential Relationships to North Atlantic Plate Tectonics and Arctic Climate Change

et al. 2019

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“…Sedimentary subunits 1b and 1c (mid-Eocene to mid-Oligocene) correspond to the lower half of the 44-18 Ma depositional hiatus inferred in the original study of the ACEX cores ; Figure 10). This time gap overlaps the main phase of Eurekan compression in North Greenland, Ellesmere Island, and Svalbard from 55 to 33 Ma (e.g., Gion et al, 2016;Oakey & Chalmers, 2012;Oakey & Stephenson, 2008;Piepjohn et al, 2016). Several recent studies suggest that the Eurekan orogeny affected large parts of the Arctic Ocean (Døssing, Hopper, et al, 2013;Døssing et al, 2014;O'Regan et al, 2008).…”

Section: 1029/2018pa003414mentioning

confidence: 84%

“…Following a prolonged phase of compression during the Eurekan and Svalbardian orogenies from 56 to 33 Ma (O'Regan et al, ), plate reconstructions show that the crust in northeast Greenland and west of Svalbard experienced trans‐extension beginning in the Oligocene around 30 Ma. Major extension followed much later (Gion et al, ). This does not fit with opening a seaway connection already at 36 Ma.…”

Section: Sedimentary and Paleoceanographic Evolution Of The Amundsen mentioning

confidence: 99%

Depositional Evolution of the Western Amundsen Basin, Arctic Ocean: Paleoceanographic and Tectonic Implications

Castro

Knutz

Hopper

et al. 2018

Paleoceanog and Paleoclimatol

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A new stratigraphic model and estimated sedimentation rates of the western Amundsen Basin, Arctic Ocean, are presented based on multichannel seismic reflection data, seismic refraction data, magnetic data, and integrated with the sedimentary sequence from the central Arctic Ocean, obtained during the Arctic Coring Expedition. This places new constraints on the postbreakup Cenozoic depositional history of the basin, the adjacent Lomonosov Ridge, and improves the understanding of the tectonic, climatic, and oceanographic conditions in the central Arctic region. Four distinct phases of basin development are proposed. During the Paleocene‐mid‐Oligocene, high sedimentation rates are linked to terrestrial input and increased pelagic deposition in a restricted basin. Deposition of sedimentary wedges and mass transport into marginal depocenters reflect a period of tectonic instability linked to compression associated with the Eurekan Orogeny in the Arctic. During the late Oligocene‐early Miocene, widespread passive infill associated with hemipelagic deposition reflects a phase of limited tectonism, most likely in a freshwater estuarine setting. During the middle Miocene, mounded sedimentary buildups along the Lomonosov Ridge suggest the onset of geostrophic bottom currents that likely formed in response to a deepening and widening of the Fram Strait beginning around 18 Ma. In contrast, the Plio‐Pleistocene stage is characterized by erosional features such as scarps and channels adjacent to levee accumulations, indicative of a change to a higher‐energy environment. These deposits are suggested to be partly associated with dense shelf water‐mass plumes driven by supercooling and brine formation over the northern Greenland continental shelf.

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Arctic rift system driven by a giant stagnant slab

Toyokuni¹,

Zhao²

2021

Preprint

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A detailed 3-D tomographic model of the whole mantle beneath the circum-Arctic region is obtained by applying an updated global tomography method to a large amount of P -wave arrival time data. Our model clearly shows the subducted Izanagi and Farallon slabs penetrating into the lower mantle beneath Eurasia and North America, respectively. In the region from Canada to Greenland, a giant stagnant slab lying below the 660-km discontinuity is revealed. Because this slab has a texture that seems to be due to subducted oceanic ridges, the slab might be composed of the Izanagi, Farallon, Kula and Vancouver slabs that had subducted during ˜80-20 Ma. During that period, a complex rift system represented by division between Canada and Greenland was developed. The oceanic ridge subduction and hot upwelling in the big mantle wedge above the stagnant slab caused a tensional stress field, which might have induced these complex tectonic events.

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A reconstruction of the Eurekan Orogeny incorporating deformation constraints

Cited by 39 publications

References 104 publications

Exhuming the Top End of North America: Episodic Evolution of the Eurekan Belt and Its Potential Relationships to North Atlantic Plate Tectonics and Arctic Climate Change

Exhuming the Top End of North America: Episodic Evolution of the Eurekan Belt and Its Potential Relationships to North Atlantic Plate Tectonics and Arctic Climate Change

Depositional Evolution of the Western Amundsen Basin, Arctic Ocean: Paleoceanographic and Tectonic Implications

Arctic rift system driven by a giant stagnant slab

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