How to identify Antarctica's "Oldest Ice" with geophysical data?
The International Partnership for Ice Core Sciences (IPICS) identified the retrieve of an "Oldest-Ice" ice core as one of the most important scientific challenges in ice core research for the near future. As the outcome of an "Oldest-Ice" workshop a general approach was recently...
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ftawi:oai:epic.awi.de:34952 2024-09-15T17:46:11+00:00 How to identify Antarctica's "Oldest Ice" with geophysical data? Eisen, Olaf 2014-03-13 https://epic.awi.de/id/eprint/34952/ https://hdl.handle.net/10013/epic.43267 unknown Eisen, O. orcid:0000-0002-6380-962X (2014) How to identify Antarctica's "Oldest Ice" with geophysical data? , DGG 2014, Karlsruhe, 10 March 0020 - 13 March 2014 . hdl:10013/epic.43267 EPIC3DGG 2014, Karlsruhe, 0020-03-10-2014-03-13 Conference notRev 2014 ftawi 2024-06-24T04:08:32Z The International Partnership for Ice Core Sciences (IPICS) identified the retrieve of an "Oldest-Ice" ice core as one of the most important scientific challenges in ice core research for the near future. As the outcome of an "Oldest-Ice" workshop a general approach was recently suggested how to combine geophysical reconnaissance, numerical ice-flow modelling and sample drilling to identify the most promising sites where about 1.5 Ma old ice could most likely be found (Fischer et al., CP, 2013). The most critical unknown parameter is the geothermal heat flow underneath the ice, followed by bed topography and integrity of internal layering. Here, we propose the combined application of geophysical methods in conjunction with existing ice-core data to improve the knowledge on physical properties of the ice and the underlaying strata. It builds on (i) conventional application of potential field geophysics (gravimetry and magnetics) to estimate subglacial geology; (ii) radar internal architecture to determine layer integrity and bedrock topography; (iii) combination of ice-core profiles with radar to determine the origin - and thus confirm isochronity and age - of internal radar layers, complemented by layer attributes; (iv) extrapolation of ice-core impurities and the related attenuation of radar waves in space along internal layers; and (v) radar and seismic wave attenuation analyses to determine the englacial temperature distribution. This approach has the potential to improve our capabilities to estimate the spatial variation of geothermal heat flux and provide spatially distributed age-depth constraints for ice-flow models. Conference Object Antarc* ice core Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) |
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Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) |
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The International Partnership for Ice Core Sciences (IPICS) identified the retrieve of an "Oldest-Ice" ice core as one of the most important scientific challenges in ice core research for the near future. As the outcome of an "Oldest-Ice" workshop a general approach was recently suggested how to combine geophysical reconnaissance, numerical ice-flow modelling and sample drilling to identify the most promising sites where about 1.5 Ma old ice could most likely be found (Fischer et al., CP, 2013). The most critical unknown parameter is the geothermal heat flow underneath the ice, followed by bed topography and integrity of internal layering. Here, we propose the combined application of geophysical methods in conjunction with existing ice-core data to improve the knowledge on physical properties of the ice and the underlaying strata. It builds on (i) conventional application of potential field geophysics (gravimetry and magnetics) to estimate subglacial geology; (ii) radar internal architecture to determine layer integrity and bedrock topography; (iii) combination of ice-core profiles with radar to determine the origin - and thus confirm isochronity and age - of internal radar layers, complemented by layer attributes; (iv) extrapolation of ice-core impurities and the related attenuation of radar waves in space along internal layers; and (v) radar and seismic wave attenuation analyses to determine the englacial temperature distribution. This approach has the potential to improve our capabilities to estimate the spatial variation of geothermal heat flux and provide spatially distributed age-depth constraints for ice-flow models. |
format |
Conference Object |
author |
Eisen, Olaf |
spellingShingle |
Eisen, Olaf How to identify Antarctica's "Oldest Ice" with geophysical data? |
author_facet |
Eisen, Olaf |
author_sort |
Eisen, Olaf |
title |
How to identify Antarctica's "Oldest Ice" with geophysical data? |
title_short |
How to identify Antarctica's "Oldest Ice" with geophysical data? |
title_full |
How to identify Antarctica's "Oldest Ice" with geophysical data? |
title_fullStr |
How to identify Antarctica's "Oldest Ice" with geophysical data? |
title_full_unstemmed |
How to identify Antarctica's "Oldest Ice" with geophysical data? |
title_sort |
how to identify antarctica's "oldest ice" with geophysical data? |
publishDate |
2014 |
url |
https://epic.awi.de/id/eprint/34952/ https://hdl.handle.net/10013/epic.43267 |
genre |
Antarc* ice core |
genre_facet |
Antarc* ice core |
op_source |
EPIC3DGG 2014, Karlsruhe, 0020-03-10-2014-03-13 |
op_relation |
Eisen, O. orcid:0000-0002-6380-962X (2014) How to identify Antarctica's "Oldest Ice" with geophysical data? , DGG 2014, Karlsruhe, 10 March 0020 - 13 March 2014 . hdl:10013/epic.43267 |
_version_ |
1810494178560311296 |