Your search keyword '"Kausch, Thore"' showing total 3 results

1. From ice core to ground-penetrating radar: representativeness of SMB at three ice rises along the Princess Ragnhild Coast, East Antarctica.

Author

Cavitte, Marie G.P., Goosse, Hugues, Wauthy, Sarah, Kausch, Thore, Tison, Jean-Louis, Van Liefferinge, Brice, Pattyn, Frank, Lenaerts, Jan T.M., and Claeys, Philippe

Subjects

GROUND penetrating radar, ICE cores, CORE drilling, ANTARCTIC ice, ICE sheets, SEA ice, PRINCESSES

Abstract

The future contributions of the Antarctic Ice Sheet to sea level rise will depend on the evolution of its surface mass balance (SMB), which could amplify/dampen mass losses increasingly observed at the ice sheet's edge. In situ constraints of SMB over annual-to-decadal timescales consist mostly of firn/ice cores that have a surface footprint $\sim$ cm $^{2}$. SMB constraints also come from climate models, which have a higher temporal resolution but a larger surface footprint of several km $^{2}$. We use ice-penetrating radar data to obtain an intermediate spatial and temporal resolution SMB record over three ice rises along the Princess Ragnhild Coast. The co-located ice cores allow us to obtain absolute radar-derived SMB rates at a multi-annual-to-decadal temporal resolution. By comparing the ice core SMB measurements and the radar-derived SMB records, we determine that pointwise measurements of SMB are representative of a small surface area, $\sim 200-500$ m radius extending from the ice core drill site for the ice rises studied here, and that the pointwise measurements are systematically 7–15 cm w.e. a $^{-1}$ lower than the mean SMB value calculated for the whole ice rises. However, ice core records are representative of an entire ice rise's temporal variability at the temporal resolution examined. [ABSTRACT FROM AUTHOR]

Published

2022

2. Impact of coastal East Antarctic ice rises on surface mass balance: insights from observations and modeling

Author

Kausch, Thore, Lhermitte, Stef, Lenaerts, Jan, Wever, Nander, Inoue, Mana, Pattyn, Frank, Sun, Sainan, Wauthy, Sarah, Tison, Jean-Louis, van de Berg, W.J., Marine and Atmospheric Research, Sub Dynamics Meteorology, Marine and Atmospheric Research, and Sub Dynamics Meteorology

Subjects

010504 meteorology & atmospheric sciences, DRONNING MAUD LAND, Ice stream, F700, F800, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Ice shelf, LAYERS, Glacier mass balance, Ice core, REGIONAL CLIMATE MODEL, CORE, Ice divide, Geosciences, Multidisciplinary, lcsh:Environmental sciences, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, Orographic lift, lcsh:GE1-350, geography, geography.geographical_feature_category, Science & Technology, lcsh:QE1-996.5, Geology, Snow, RADAR, lcsh:Geology, Geography, Physical, SNOW ACCUMULATION, VARIABILITY, Oceanography, Physical Geography, Physical Sciences, MAP, Climate model, Sciences exactes et naturelles

Abstract

About 20 % of all snow accumulation in Antarctica occurs on the ice shelves. There, ice rises control the spatial surface mass balance (SMB) distribution by inducing snowfall variability and wind erosion due to their topography. Moreover these ice rises buttress the ice flow and represent ideal drilling locations for ice cores. In this study we assess the connection between snowfall variability and wind erosion to provide a better understanding of how ice rises impact SMB variability, how well this is captured in the regional atmospheric climate model RACMO2 and the implications of this SMB variability for ice rises as an ice core drilling site. By combining ground-penetrating radar (GPR) profiles from two ice rises in Dronning Maud Land with ice core dating, we reconstruct spatial and temporal SMB variations from 1983 to 2018 and compare the observed SMB with output from RACMO2 and SnowModel. Our results show snowfall-driven differences of up to 1.5 times higher SMB on the windward side of both ice rises than on the leeward side as well as a local erosion-driven minimum at the ice divide of the ice rises. RACMO2 captures the snowfall-driven differences but overestimates their magnitude, whereas the erosion on the peak can be reproduced by SnowModel with RACMO2 forcing. Observed temporal variability of the average SMBs, retrieved from the GPR data for four time intervals in the 1983–2018 range, are low at the peak of the easternmost ice rise (∼0.06 mw.e.yr-1), while they are higher (∼0.09 mw.e.yr-1) on the windward side of the ice rise. This implies that at the peak of the ice rise, higher snowfall, driven by orographic uplift, is balanced out by local erosion. As a consequence of this, the SMB recovered from the ice core matches the SMB from the GPR at the peak of the ice rise but not at the windward side of the ice rise, suggesting that the SMB signal is damped in the ice core., info:eu-repo/semantics/published

Published

2020

3. Interseismic and Postseismic Shallow Creep of the North Qaidam Thrust Faults Detected with a Multitemporal InSAR Analysis.

Author

Daout, Simon, Sudhaus, Henriette, Kausch, Thore, Steinberg, Andreas, and Dini, Benedetta

Subjects

GEOLOGIC faults, EARTHQUAKES, REMOTE sensing, GEODESY, DEFORMATIONS (Mechanics)

Abstract

Understanding the mechanisms by which earthquake cycles produce folding and accommodate shortening is essential to quantify the seismic potential of active faults and integrate aseismic slip within our understanding of the physical mechanisms of the long‐term deformation. However, measuring such small deformation signals in mountainous areas is challenging with current space‐geodesy techniques, due to the low rates of motion relative to the amplitude of the noise. Here we successfully carry out a multitemporal Interferometric Synthetic Aperture Radar analysis over the North Qaidam fold‐thrust system in NE Tibet, where eight Mw> 5.2 earthquakes occurred between 2003 and 2009. We report various cases of aseismic slip uplifting the thickened crust at short wavelengths. We provide a rare example of a steep, shallow, 13‐km‐long and 6‐km‐wide afterslip signal that coincides spatially with an anticline and that continues into 2011 in response to a Mw 6.3 event in 2003. We suggest that a buried seismic slip during the 2003 earthquake has triggered both plastic an‐elastic folding and aseismic slip on the shallow thrusts. We produce a first‐order two‐dimensional model of the postseismic surface displacements due to the 2003 earthquake and highlight a segmented slip on three fault patches that steepen approaching the surface. This study emphasizes the fundamental role of shallow aseismic slip in the long‐term and permanent deformation of thrusts and folds and the potential of Interferometric Synthetic Aperture Radar for detecting and characterizing the spatiotemporal behavior of aseismic slip over large mountainous regions. Key Points: InSAR time series displacement maps have been constructed for a 300 × 300 km2 area in NE TibetSteady‐state creep from 2003 to 2011 has been identified across several active faults within the Qaidam basinA major postseismic creep event uplifting an active fold by 6 cm in 3 years has been detected [ABSTRACT FROM AUTHOR]

Published

2019