Climatic imprint in the mechanical properties of ice sheets and its effect on ice flow: Observations from South Pole and EPICA Dome C ice cores
- 1British Antarctic Survey, Physical Science Division, Cambridge, United Kingdom of Great Britain and Northern Ireland (cama@bas.ac.uk)
- 2University of Washington: Seattle, WA, US
- 3Univ. Grenoble Alpes / CNRS: Grenoble, FR
- 4Eberhard Karls Universität Tübingen: Tubingen, Baden-Württemberg, DE
The climatic conditions over ice sheets at the time of snow deposition and compaction imprint distinctive crystallographic properties to the resulting ice. As the snow gets buried, its macroscopic structure evolves due to vertical compression but retains traces of the climatic imprint that generate distinctive mechanical, thermal and optical properties. Because climate alternates between glaciar periods, that are colder and dustier, and interglacial periods, the ice sheets are composed from layers with alternating mechanical properties. Here we compare ice core dust content and crystal orientation fabrics, from the ice core records, with englacial vertical strain-rates, measured with a phase-sensitive radar (ApRES), at South Pole and EPICA Dome C ice cores. Similarly to previous observations, we show that ice deposited during glacial periods develops stronger crystal orientation fabrics. In addition, we show that ice deposited during glacial periods is harder to vertically compress and horizontally extend, up to about 3 times, but softer to shear. These variations in mechanical properties are typically ignored in ice-flow modelling but they could be critical to interpret ice core records. Also, we show that the changes in crystal orientation fabrics due to transitions from interglacial to glacial conditions can be detected by phase-sensitive radar. This information can be used to constrain age-depth in future ice-core locations.
How to cite: Martin, C., Conway, H., Koutnik, M., Ritz, C., Bauska, T., Drews, R., and Ershadi, M. R.: Climatic imprint in the mechanical properties of ice sheets and its effect on ice flow: Observations from South Pole and EPICA Dome C ice cores, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-19541, https://doi.org/10.5194/egusphere-egu2020-19541, 2020