New Magnetic Anomaly Map of the Antarctic

Golynsky, Alexander; Ferraccioli, Fausto; Hong, Jong Kuk; Golynsky, Dmitry; Frese, Ralph R. B. von; Young, D. A.; Blankenship, D. D.; Holt, J. W.; Иванов, С. В.; Kiselev, Alexander V.; Masolov, V. N.; Eagles, Graeme; Gohl, Karsten; Jokat, Wilfried; Damaske, Detlef; Finn, Carol A.; Aitken, Alan; Bell, Robin E.; Armadillo, Egidio; Jordan, Tom A.; Greenbaum, J. S.; Bozzo, E.; Caneva, G.; Forsberg, R.; Ghidella, Marta E.; Galindo-Zaldı́var, Jesús; Bohoyo, Fernando; Martos, Yasmina M.; Nogi, Yoshifumi; Quartini, Enrica; Kim, Hyung Rae; Roberts, Jason L.

doi:10.1029/2018gl078153

Cited by 99 publications

(108 citation statements)

References 88 publications

(133 reference statements)

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“…1.3 to 1.0 Ga) are also observed, and their origin could be located in a putative~1,000-km-distant source region in the GSM province, where Ferraccioli et al (2011) hypothesized that a major coeval orogenic belt exists, based on their aeromagnetic and airborne gravity interpretation. Aeromagnetic studies also suggest that the cratonal margin of EANT, at least at crustal level, gets much closer to the coast along our modeling profile compared to the northern parts, where the Ross Orogen appears to be considerably wider (Ferraccioli, Armadillo, Jordan, et al, 2009;Ferraccioli, Armadillo, Zunino, et al, 2009;Ferraccioli et al, 2002;Golynsky et al, 2018).…”

Section: 1029/2018gc008111mentioning

confidence: 66%

“…The lithosphere of the Antarctic continent is still poorly known, despite several major airborne geophysical campaigns including the acquisition of extensive gravity and magnetic measurements and recent continental‐scale data compilations (e.g., Aitken et al, , Aitken et al, ; Chiappini et al, ; Ferraccioli, Armadillo, Jordan, et al, , Ferraccioli, Armadillo, Zunino, et al, , Ferraccioli et al, ; Scheinert et al, ; Golynsky et al, , ) and a variety of recent seismological studies (e.g., An et al, ; Chaput et al, ; Hansen et al, ; Ramirez et al, ; Ramirez et al, ; Shen et al, ; Shen et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Moho Depths of Antarctica: Comparison of Seismic, Gravity, and Isostatic Results

Pappa

Ebbing

Ferraccioli

2019

Geochem Geophys Geosyst

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The lithospheric structure of Antarctica is still underexplored. Moho depth estimate studies are in disagreement by more than 10 km in several regions, including, for example, the hinterland of the Transantarctic Mountains. Taking account the sparseness of seismological stations and the nonuniqueness of potential field methods, inversions of Moho depth are performed here based on satellite gravity data in combination with currently available seismically constrained Moho depth estimates. Our results confirm that a lower density contrast at the Moho is present under East Antarctica than beneath West Antarctica. A comparison between the Moho depth derived from our inversion and an Airy‐isostatic Moho model also reveals a spatially variable buoyancy contribution from the lithospheric mantle beneath contrasting sectors of East Antarctica. Finally, to test the plausibility of different Moho depths scenarios for the Transantarctic Mountains‐Wilkes Subglacial Basin system, we present 2‐D lithospheric models along the Trans‐Antarctic Mountain Seismic Experiment/Gamburtsev Mountain Seismic experiment seismic profile. Our models show that if a moderately depleted lithospheric mantle of inferred Proterozoic age underlies the region, then a shallower Moho is more likely beneath the Wilkes Subglacial Basin. If however, refertilization processes occurred in the upper mantle, for example, in response to Ross‐age subduction, then a deeper Moho scenario is preferred. We conclude that 3‐D lithospheric modeling, coupled with the availability of new seismic information in the hinterland of the Transantarctic Mountains, is required to help resolve this controversy, thereby also reducing the ambiguities in geothermal heat flux estimation beneath this key part of the East Antarctic Ice Sheet.

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Section: 1029/2018gc008111mentioning

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Moho Depths of Antarctica: Comparison of Seismic, Gravity, and Isostatic Results

Pappa

Ebbing

Ferraccioli

2019

Geochem Geophys Geosyst

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“…The thick ice sheet cover and the remoteness of Antarctica make geological and geophysical investigations particularly challenging. Hence, Hdespite the large extent of recent aeromagnetic 31 and aerogravity data coverage 32 , a continental-scale tectonic elements map that is required to aid global plate reconstructions 33 remains to be defined.…”

Section: Resultsmentioning

confidence: 99%

Earth tectonics as seen by GOCE - Enhanced satellite gravity gradient imaging

Ebbing

Haas

Ferraccioli

et al. 2018

Sci Rep

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Curvature components derived from satellite gravity gradients provide new global views of Earth’s structure. The satellite gravity gradients are based on the GOCE satellite mission and we illustrate by curvature images how the Earth is seen differently compared to seismic imaging. Tectonic domains with similar seismic characteristic can exhibit distinct differences in satellite gravity gradients maps, which points to differences in the lithospheric build-up. This is particularly apparent for the cratonic regions of the Earth. The comparisons demonstrate that the combination of seismological, and satellite gravity gradient imaging has significant potential to enhance our knowledge of Earth’s structure. In remote frontiers like the Antarctic continent, where even basic knowledge of lithospheric scale features remains incomplete, the curvature images help unveil the heterogeneity in lithospheric structure, e.g. between the composite East Antarctic Craton and the West Antarctic Rift System.

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“…In contrast to previous studies, the MCMC approach would still leave some freedom for lateral variance of the thermal parameters, while at the same time it would be geologically constrained. For West Antarctica, such an approach is not possible, but here one should make use of the wealth of geophysical high-resolution data acquired over the last years (e.g., Golynsky et al, 2018;Scheinert et al, 2016;Shen et al, 2018) and couple these in the analysis.…”

Section: Discussionmentioning

confidence: 99%

Geothermal Heat Flux in Antarctica: Assessing Models and Observations by Bayesian Inversion

2020

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Geothermal heat flux under the Antarctic ice is one of the least known parameters. Different methods (based on e.g., magnetic or seismic data) have been applied in recent years to quantify the thermal structure and the geothermal heat flux, resulting in vastly different estimates. In this study, we use a Bayesian Monte-Carlo-Markov-Chain approach to explore the consistency of such models and to which degree lateral variations of the thermal parameters are required. Hereby, we evaluate the input from different lithospheric models and how they influence surface heat flux. We demonstrate that both Curie isotherm and heat production are dominating parameters for the thermal calculation and that use of incorrect models or sparsely available data lead to unreliable results. As an alternative approach, geological information should be coupled with geophysical data analysis, as we demonstrate for the Antarctic Peninsula.

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New Magnetic Anomaly Map of the Antarctic

Cited by 99 publications

References 88 publications

Moho Depths of Antarctica: Comparison of Seismic, Gravity, and Isostatic Results

Moho Depths of Antarctica: Comparison of Seismic, Gravity, and Isostatic Results

Earth tectonics as seen by GOCE - Enhanced satellite gravity gradient imaging

Geothermal Heat Flux in Antarctica: Assessing Models and Observations by Bayesian Inversion

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