East Antarctic rifting triggers uplift of the Gamburtsev Mountains

Ferraccioli, Fausto; Finn, Carol A.; Jordan, Tom A.; Bell, Robin E.; Anderson, Lester; Damaske, Detlef

doi:10.1038/nature10566

Cited by 206 publications

(296 citation statements)

References 45 publications

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“…It can be seen that the ice stream is >3 km deep here, with a sharp border to higher subglacial terrain towards the southern side of the ice stream. The gravity signatures and bedrock maps of Figure 7 also show SW-NE-striking features, probably associated with subglacial fault systems (Paxman et al 2017), and also a highland-like subglacial region to the east of Recovery Lakes, towards the Gamburtsev Subglacial Mountains region (Ferraccioli et al 2011;Paxman et al 2016). The SW-NE-striking features also show up in the magnetic data in Figure 9.…”

Section: Airbourne Surveys Of Recovery Lakes Region 31mentioning

confidence: 55%

Exploring the Recovery Lakes region and interior Dronning Maud Land, East Antarctica, with airborne gravity, magnetic and radar measurements

Forsberg

Olesen

Ferraccioli

et al. 2017

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Long-range airborne geophysical measurements were carried out in the ICEGRAV campaigns, covering hitherto unexplored parts of interior East Antarctica and part of the Antarctic Peninsula. The airborne surveys provided a regional coverage of gravity, magnetic and icepenetrating radar measurements for major Dronning Maud Land ice stream systems, from the grounding lines up to the Recovery Lakes drainage basin, and filled in major data voids in Antarctic data compilations, such as AntGP for gravity data, ADMAP for magnetic data and BEDMAP2 for ice thickness data and the sub-ice topography. We present the first maps of gravity, magnetic and ice thickness data and bedrock topography for the region and show examples of bedrock topography and basal reflectivity patterns. The 2013 Recovery Lakes campaign was carried out with a British Antarctic Survey Twin Otter aircraft operating from the Halley and Belgrano II stations, as well as a remote field camp located at the Recovery subglacial Lake B site. Gravity measurements were the primary driver for the survey, with two airborne gravimeters (Lacoste and Romberg and Chekan-AM) providing measurements at an accuracy level of around 2 mGal r.m.s., supplementing GOCE (Gravity Field and Steady-State Ocean Circulation Explorer) satellite data and confirming an excellent sub-milligal agreement between satellite and airborne data at longer wavelengths.Gold Open Access: This article is published under the terms of the CC-BY 3.0 license.

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Section: Airbourne Surveys Of Recovery Lakes Region 31mentioning

confidence: 55%

Exploring the Recovery Lakes region and interior Dronning Maud Land, East Antarctica, with airborne gravity, magnetic and radar measurements

Forsberg

Olesen

Ferraccioli

et al. 2017

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“…Regional plume-related dynamics in the deep lithosphere have been postulated as the dominant trigger for this thermal activity, with a possible contributing influence from the adjacent West Antarctic Block, a process that has also been invoked in earlier studies to account for the regional uplift in East Antarctica such as in the GamburtsevÁVostok areas (Studinger et al 2003;Bell et al 2006). However, a recent study by Ferraccioli et al (2011) negated this hypothesis and interpreted the feature to be a compositional Airy compensation. Continental flood basalts are known from western Dronning Maud Land and the Transantarctic Mountains which are regarded as manifestations of the KarooÁ Maud mantle super-plume activities at about 180 Mya (e.g., Bormann & Fritzsche 1995), which enabled subsequent Gondwanaland break-up (e.g., Storey 1995;Raval & Veeraswamy 2003).…”

Section: Geological Implicationsmentioning

confidence: 70%

Electrical structure beneath Schirmacher Oasis, East Antarctica: a magnetotelluric study

Murthy

Veeraswamy²,

Harinarayana³

et al. 2013

Polar Research

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Maitri Station (70.76°S; 11.73°E) is located in Schirmacher Oasis, a coastal nunatak in north-central Dronning Maud Land covering an area of 35 km2. Here, we report results from the first magnetotelluric experiments and delineate the deep electrical conductivity structure under Schirmacher Oasis using the data acquired during the 24th Indian Antarctic Scientific Expedition. The magnetotelluric method has the advantage of shallow to deeper level coverage as the data acquisition covers a wide frequency band of 10−3–103 Hz, permitting different penetration depths depending on the frequency and conductivity of the layer under investigation. The modelling results indicate the presence of a highly resistive (8000–10 000 ohm m) upper crust, which shows a lateral variation in thickness from 20 km (below site 6) in the east to 10 km (between sites 1 and 2) in the west. It is underlain by a less resistive (500–600 ohm m) lower crust. The highly resistive upper crustal structure supports the existing notion that western Dronning Maud Land is a stable, cratonic platform. Results of free-air gravity, seismic, geomagnetic and surface wave dispersion investigations in East Antarctica also indicate a cratonic-type crust. The results of our study allow us to identify a westward thinning of the upper crust with a marked boundary between sites 1 and 2. We also find evidence for the continuity of the Mozambique mobile belt in East Antarctica on the western side of Schirmacher Oasis

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“…6b). This proposed path also corresponds with the eastern branch of the East Antarctic Rift System (Figs 2 & 6) (Ferraccioli et al 2011), a prominent subglacial topographical feature that has a western branch in the Lambert Graben and is likely to follow older geological boundaries. Although Fitzsimons (2003) favoured a Pan-African age for this structure, there is evidence for metamorphism and magmatism at 1090-1060, 800-650 and 550-500 Ma in the Pinjarra Orogen of Western Australia (Fig.…”

Section: Joining the Dotsmentioning

confidence: 99%

Antarctica and supercontinent evolution: historical perspectives, recent advances and unresolved issues

Harley

Fitzsimons

Zhao

2013

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The Antarctic rock record spans some 3.5 billion years of history, and has made important contributions to our understanding of how Earth's continents assemble and disperse through time. Correlations between Antarctica and other southern continents were critical to the concept of Gondwana, the Palaeozoic supercontinent used to support early arguments for continental drift, while evidence for Proterozoic connections between Antarctica and North America led to the 'SWEAT' configuration (linking SW USA to East Antarctica) for an early Neoproterozoic supercontinent known as Rodinia. Antarctica also contains relicts of an older Palaeo-to Mesoproterozoic supercontinent known as Nuna, along with several Archaean fragments that belonged to one or more 'supercratons' in Neoarchaean times. It thus seems likely that Antarctica contains remnants of most, if not all, of Earth's supercontinents, and Antarctic research continues to provide insights into their palaeogeography and geological evolution. One area of research is the latest Neoproterozoic-Mesozoic active margin of Gondwana, preserved in Antarctica as the Ross Orogen and a number of outboard terranes that now form West Antarctica. Major episodes of magmatism, deformation and metamorphism along this palaeo-Pacific margin at 590 -500 and 300-230 Ma can be linked to reduced convergence along the internal collisional orogens that formed Gondwana and Pangaea, respectively; indicating that accretionary systems are sensitive to changes in the global plate tectonic budget. Other research has focused on Grenville-age (c. 1.0 Ga) and PanAfrican (c. 0.5 Ga) metamorphism in the East Antarctic Craton. These global-scale events record the amalgamation of Rodinia and Gondwana, respectively. Three coastal segments of Grenville-age metamorphism in the Indian Ocean sector of Antarctica are each linked to the c. 1.0 Ga collision between older cratons but are separated by two regions of pervasive Pan-African metamorphism ascribed to Neoproterozoic ocean closure. The tectonic setting of these events is poorly constrained given the sparse exposure, deep erosion level and likelihood that younger metamorphic events have reactivated older structures. The projection of these orogens under the ice is also controversial, but it is likely that at least one of the Pan-African orogens links up with the Shackleton Range on the palaeo-Pacific margin of the craton. Sedimentary detritus and glacial erratics at the edge of the ice sheet provide evidence for the c.

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East Antarctic rifting triggers uplift of the Gamburtsev Mountains

Cited by 206 publications

References 45 publications

Exploring the Recovery Lakes region and interior Dronning Maud Land, East Antarctica, with airborne gravity, magnetic and radar measurements

Exploring the Recovery Lakes region and interior Dronning Maud Land, East Antarctica, with airborne gravity, magnetic and radar measurements

Electrical structure beneath Schirmacher Oasis, East Antarctica: a magnetotelluric study

Antarctica and supercontinent evolution: historical perspectives, recent advances and unresolved issues

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