A quantitative method for deriving salinity of subglacial water using ground-based transient electromagnetics

Liquid water can exist at temperatures well below freezing beneath glaciers and ice sheets, where subglacial water systems, fresh and saline, have been shown to host unique microbial ecosystems. Geophysical techniques sensitive to fluid-content contrasts, e.g. electromagnetics, can characterize subg...

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Vydáno v:	Journal of glaciology Ročník 68; číslo 268; s. 319 - 336
Hlavní autoři:	Killingbeck, Siobhan F., Dow, Christine F., Unsworth, Martyn J.
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Cambridge, UK Cambridge University Press 01.04.2022
Témata:	Algorithms Bayesian analysis Cold Depth Electrical resistivity Electromagnetic radiation Feasibility studies Freezing Geophysical methods Glaciation Glaciers Groundwater Hydrology Ice Ice sheets Ice thickness Lakes Mathematical models Microorganisms Probability theory Radar Radar data Saline water Salinity Salinity effects Sediments Seismic data Seismological data subglacial lake Subglacial lakes Subglacial water transient electromagnetics Water Antarctica subglacial water transient electromagnetics subglacial lake Salinity
ISSN:	0022-1430, 1727-5652
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Shrnutí:	Liquid water can exist at temperatures well below freezing beneath glaciers and ice sheets, where subglacial water systems, fresh and saline, have been shown to host unique microbial ecosystems. Geophysical techniques sensitive to fluid-content contrasts, e.g. electromagnetics, can characterize subglacial water and its salinity. Here, we assess the ground-based transient electromagnetic (TEM) method for deriving the resistivity and salinity of subglacial water. We adapt an existing open-source Bayesian inversion algorithm, which uses independent depth constraints, to output posterior distributions of resistivity and pore fluid salinity with depth. A variety of synthetic models, including a thin (5 m), conductive (0.16 Ωm), hypersaline (147 psu) subglacial lake, are used to evaluate the TEM method for imaging under 800 m-thick ice. The study demonstrates that TEM methods can resolve conductive, saline bodies accurately using external depth constraints, for example, from radar or seismic data. The depth resolution of TEM can be limited beneath deep (>800 m), thick (>50 m) conductive, water bodies and additional constraints from passive electromagnetic (EM) methods could be used to reduce ambiguities in the TEM results. Subsequently, non-invasive active and passive EM methods could provide profound insights into remote aqueous systems under glaciers and ice sheets.
Bibliografie:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14
ISSN:	0022-1430 1727-5652
DOI:	10.1017/jog.2021.94