Magnetotelluric investigation of the Vestfold Hills and Rauer Group, East Antarctica

Peacock, Jared; Selway, Kate

doi:10.1002/2015jb012677

Cited by 17 publications

(13 citation statements)

References 76 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although theoretical considerations suggest that departures from the MT plane-wave source-field assumption may be prevalent at the poles due to the presence of the polar atmospheric electrojets (Pirjola, 1998), Beblo and Liebig (1990) showed that MT impedance responses from different time segments remain stationary despite clear variations in source strength associated with the electrojet. This conclusion is also supported by the lack of source-effect complications in more recent datasets others, 1996, 2004;Peacock and Selway, 2016).…”

Section: Previous Em Surveys In Antarcticasupporting

confidence: 68%

“…Due to the high resistivity of firn, the contact resistance of the electric bipoles used to measure the telluric fields can be as high as 1 MΩ leading to enhanced capacitive coupling with the ground, and so specialized ultra-high-input impedance buffer amplifiers and electrodes must be used to minimize these effects (Zonge and Hughes, 1985). Wannamaker and others (2004) and Peacock and Selway (2016) have demonstrated the effectiveness of this approach for measuring electric fields in Antarctica.…”

Section: Discussionmentioning

confidence: 99%

“…Beblo and Liebig (1990) present the first quantitative analysis of Antarctic MT data, describing a suite of four stations collected on Priestly Glacier, North Victoria Land, with encouraging results for investigating sub-ice sedimentary basins. More recent studies have concentrated on using low-frequency MT data to study deep crustal and upper mantle tectonics (Wannamaker and others, 1996(Wannamaker and others, , 2004(Wannamaker and others, , 2012Peacock and Selway, 2016). Although theoretical considerations suggest that departures from the MT plane-wave source-field assumption may be prevalent at the poles due to the presence of the polar atmospheric electrojets (Pirjola, 1998), Beblo and Liebig (1990) showed that MT impedance responses from different time segments remain stationary despite clear variations in source strength associated with the electrojet.…”

Section: Previous Em Surveys In Antarcticamentioning

confidence: 99%

See 2 more Smart Citations

The feasibility of imaging subglacial hydrology beneath ice streams with ground-based electromagnetics

Key

Siegfried

2017

J. Glaciol.

View full text Add to dashboard Cite

ABSTRACT. Subglacial hydrologic systems in Antarctica and Greenland play a fundamental role in ice-sheet dynamics, yet critical aspects of these systems remain poorly understood due to a lack of observations. Ground-based electromagnetic (EM) geophysical methods are established for mapping groundwater in many environments, but have never been applied to imaging lakes beneath ice sheets. Here, we study the feasibility of passive-and active-source EM imaging for quantifying the nature of subglacial water systems beneath ice streams, with an emphasis on the interfaces between ice and basal meltwater, as well as deeper groundwater in the underlying sediments. We describe a suite of model studies that exam the data sensitivity as a function of ice thickness, water conductivity and hydrologic system geometry for models representative of a subglacial lake and a grounding zone estuary. We show that EM data are directly sensitive to groundwater and can image its lateral and depth extent. By combining the conductivity obtained from EM data with ice thickness and geological structure from conventional geophysical techniques, such as ground-penetrating radar and active seismic surveying, EM data have the potential to provide new insights on the interaction between ice, rock and water at critical ice-sheet boundaries.

show abstract

Section: Previous Em Surveys In Antarcticasupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Section: Previous Em Surveys In Antarcticamentioning

confidence: 99%

See 1 more Smart Citation

The feasibility of imaging subglacial hydrology beneath ice streams with ground-based electromagnetics

Key

Siegfried

2017

J. Glaciol.

View full text Add to dashboard Cite

show abstract

“…The MT method assumes that the Earth's magnetic field behaves as a homogeneous plane wave (Cagniard, 1953), but in auroral regions close to the magnetic poles, this assumption may break down (e.g., Hill, 2020; Jones & Spratt, 2002; Peacock & Selway, 2016; Smirnov & Egbert, 2012). We calculated impedance tensors through separate processing of daytime and nighttime data for the long‐period station and found no evidence of temporal changes in the source field (Figure 2b), suggesting that the data are not impacted by non‐planar source field effects.…”

Section: Datamentioning

confidence: 99%

Magnetotelluric Constraints on the Temperature, Composition, Partial Melt Content, and Viscosity of the Upper Mantle Beneath Svalbard

Selway

Smirnov

Beka

et al. 2020

Geochem Geophys Geosyst

View full text Add to dashboard Cite

Long-period magnetotelluric (MT) data can be used to interpret upper mantle temperature, hydrogen content, and the presence of partial melt, all of which strongly influence mantle viscosity. We have collected the first long-period MT data in Svalbard and have combined them with preexisting broadband MT data to produce a model of the electrical resistivity of Svalbard's upper mantle. Asthenospheric resistivities are low compared to stable continental settings but more comparable to young oceanic asthenosphere, suggesting that the physical state of Svalbard's upper mantle is controlled by its proximity to the Mid-Atlantic Ridge. Interpretation of the MT model using a petrologically constrained genetic algorithm approach shows that partial melt is present in the uppermost asthenosphere beneath Svalbard. This is the first direct evidence of partial melt in Svalbard's asthenosphere from deep geophysical soundings. Viscosities calculated from the geophysical data show a low viscosity layer (~10 18 Pa s) coincident with the partial melt layer, underlain by a higher viscosity layer (~10 20 Pa s) extending to the transition zone. Viscosities calculated from glacial isostatic adjustment (GIA) data in Svalbard show a considerable range due mainly to uncertainties in past ice sheet models. Improved constraints on Svalbard's mantle viscosity from geophysical data may help to improve these GIA models.

show abstract

“…MT results local to the largest population centre Longyearbyen identified a conductivity structure which is suggested as favourable for geothermal heat storage with a zone of high conductivity in the mid-crust 'sealed' by overlying and surrounding resistive bodies . Elevated heat flow rates ranging from 80 to 130 mW m −2 have been reported for the area (Vagnes and Amundsen 1993;Khutorskoi et al 2009;Slagstad et al 2009;Pascal et al 2011) due to local deep faulting, and a thinned (~ 100 km) lithosphere (Bergh and Grogan 2003) combined with the local conductivity structure makes further evaluation of the areas geothermal resource potential warranted. Further a near-surface resistive layer extending to a depth of ~ 120 m represents the permafrost zone of primarily unconsolidated gravels ; however, there is significant heterogeneity in the thickness of the permafrost layer with a max depth of ~ 250 m and a general thinning westward (towards the coast).…”

Section: Svalbard Archipelago Norwaymentioning

confidence: 99%

On the Use of Electromagnetics for Earth Imaging of the Polar Regions

Hill

2019

Surv Geophys

View full text Add to dashboard Cite

The polar regions are host to fundamental unresolved challenges in Earth studies. The nature of these regions necessitates the use of geophysics to address these issues, with electromagnetic and, in particular, magnetotelluric studies finding favour and being applied over a number of different scales. The unique geography and climatic conditions of the polar regions means collecting magnetotelluric data at high latitudes, which presents challenges not typically encountered and may result in significant measurement errors. (1) The very high contact resistance between electrodes and the surficial snow and ice cover (commonly MΩ) can interfere with the electric field measurement. This is overcome by using custom-designed amplifiers placed at the active electrodes to buffer their high impedance contacts.(2) The proximity to the geomagnetic poles requires verification of the fundamental assumption in magnetotellurics that the magnetic source field is a vertically propagating, horizontally polarised plane wave. Behaviour of the polar electro-jet must be assessed to identify increased activity (high energy periods) that create strong current systems and may generate non-planar contributions. (3) The generation of 'blizstatic', localised random electric fields caused by the spin drift of moving charged snow and ice particles that produce significant noise in the electric fields during periods of strong winds. At wind speeds above ~ 10 m s −1 , the effect of the distortion created by the moving snow is broad-band. Station occupation times need to be of sufficient length to ensure data are collected when wind speed is low. (4) Working on glaciated terrain introduces additional safety challenges, e.g., weather, crevasse hazards, etc. Inclusion of a mountaineer in the team, both during the site location planning and onsite operations, allows these hazards to be properly managed. Examples spanning studies covering development and application of novel electromagnetic approaches for the polar regions as well as results from studies addressing a variety of differing geologic questions are presented. Electromagnetic studies focusing on near-surface hydrologic systems, glacial and ice sheet dynamics, as well as large-scale volcanic and tectonic problems are discussed providing an overview of the use of electromagnetic methods to investigate fundamental questions in solid earth studies that have both been completed and are currently ongoing in polar regions.

show abstract

Magnetotelluric investigation of the Vestfold Hills and Rauer Group, East Antarctica

Cited by 17 publications

References 76 publications

The feasibility of imaging subglacial hydrology beneath ice streams with ground-based electromagnetics

The feasibility of imaging subglacial hydrology beneath ice streams with ground-based electromagnetics

Magnetotelluric Constraints on the Temperature, Composition, Partial Melt Content, and Viscosity of the Upper Mantle Beneath Svalbard

On the Use of Electromagnetics for Earth Imaging of the Polar Regions

Contact Info

Product

Resources

About