Abstract
Abstract. Ice has a very high plastic anisotropy with easy dislocation glide on basal planes, while glide on non-basal planes is much harder. Basal glide involves dislocations with the Burgers vector b = 〈a〉, while glide on non-basal planes can involve dislocations with b = 〈a〉, b = [c], and b = 〈c + a〉. During the natural ductile flow of polar ice sheets, most of the deformation is expected to occur by basal slip accommodated by other processes, including non-basal slip and grain boundary processes. However, the importance of different accommodating processes is controversial. The recent application of micro-diffraction analysis methods to ice, such as X-ray Laue diffraction and electron backscattered diffraction (EBSD), has demonstrated that subgrain boundaries indicative of non-basal slip are present in naturally deformed ice, although so far the available data sets are limited. In this study we present an analysis of a large number of subgrain boundaries in ice core samples from one depth level from two deep ice cores from Antarctica (EPICA-DML deep ice core at 656 m of depth) and Greenland (NEEM deep ice core at 719 m of depth). EBSD provides information for the characterization of subgrain boundary types and on the dislocations that are likely to be present along the boundary. EBSD analyses, in combination with light microscopy measurements, are presented and interpreted in terms of the dislocation slip systems. The most common subgrain boundaries are indicative of basal 〈a〉 slip with an almost equal occurrence of subgrain boundaries indicative of prism [c] or 〈c + a〉 slip on prism and/or pyramidal planes. A few subgrain boundaries are indicative of prism 〈a〉 slip or slip of 〈a〉 screw dislocations on the basal plane. In addition to these classical polygonization processes that involve the recovery of dislocations into boundaries, alternative mechanisms are discussed for the formation of subgrain boundaries that are not related to the crystallography of the host grain.The finding that subgrain boundaries indicative of non-basal slip are as frequent as those indicating basal slip is surprising. Our evidence of frequent non-basal slip in naturally deformed polar ice core samples has important implications for discussions on ice about plasticity descriptions, rate-controlling processes which accommodate basal glide, and anisotropic ice flow descriptions of large ice masses with the wider perspective of sea level evolution.
Highlights
Ice, the extensive amounts found in the polar ice sheets, impacts the global climate directly by changing the albedo and indirectly by supplying an enormous water reservoir that affects sea level change (IPCC, 2014, 2007; Stocker et al, 2010; Lemke et al, 2007; Bindoff et al, 2007)
Two SGB types are labelled in Fig. 3a: a P-type boundary with a trace parallel to the basal plane and an N-type boundary with a trace that is predominantly perpendicular to the basal plane. 3.2 Misorientation angle range for subgrain boundaries using electron backscattered diffraction (EBSD) Approximately 230 individual SGBs were measured in the EDML samples and ∼ 180 in the NEEM samples using EBSD
The different SGB types were analysed using light microscopy (LM) images and EBSD-mapped data (Figs. 3 and 4), and the trace of the boundary and the rotation axis, R, were used to determine the slip systems. 3.3.1 Subgrain boundary traces Small rotation differences were observed between many EBSD images and the LM images
Summary
The extensive amounts found in the polar ice sheets, impacts the global climate directly by changing the albedo and indirectly by supplying an enormous water reservoir that affects sea level change (IPCC, 2014, 2007; Stocker et al, 2010; Lemke et al, 2007; Bindoff et al, 2007). The discharge of material into the oceans is controlled by the melt excess over snow accumulation and the dynamic flow of ice (Hock, 2005). Fast discharge by ice streams up to several hundred metres per year in surface velocity (Joughin et al, 2015) includes the rapid transportation of ice towards coasts by sliding over the bedrock due to various subglacial processes (Vaughan and Arthern, 2007; Hughes, 2009; Thoma et al, 2010; Beem et al, 2010; Wolovick and Creyts, 2016) and the flow of material towards these rapid ice streams by internal deformation of the whole ice body. Weikusat et al.: EBSD analysis of subgrain boundaries and dislocation slip systems tion is responsible for the required convergent flow geometries at the onset of ice streams (Bons et al, 2016), at only a few centimetres to metres per year
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