Abstract
Abstract. The subglacial environment of the Greenland Ice Sheet (GrIS) is poorly constrained both in its bulk properties, for example geology, the presence of sediment, and the presence of water, and interfacial conditions, such as roughness and bed rheology. There is, therefore, limited understanding of how spatially heterogeneous subglacial properties relate to ice-sheet motion. Here, via analysis of 2 decades of radio-echo sounding data, we present a new systematic analysis of subglacial roughness beneath the GrIS. We use two independent methods to quantify subglacial roughness: first, the variability in along-track topography – enabling an assessment of roughness anisotropy from pairs of orthogonal transects aligned perpendicular and parallel to ice flow and, second, from bed-echo scattering – enabling assessment of fine-scale bed characteristics. We establish the spatial distribution of subglacial roughness and quantify its relationship with ice flow speed and direction. Overall, the beds of fast-flowing regions are observed to be rougher than the slow-flowing interior. Topographic roughness exhibits an exponential scaling relationship with ice surface velocity parallel, but not perpendicular, to flow direction in fast-flowing regions, and the degree of anisotropy is correlated with ice surface speed. In many slow-flowing regions both roughness methods indicate spatially coherent regions of smooth beds, which, through combination with analyses of underlying geology, we conclude is likely due to the presence of a hard flat bed. Consequently, the study provides scope for a spatially variable hard- or soft-bed boundary constraint for ice-sheet models.
Highlights
In this paper, using 2 decades of Center for Remote Sensing of Ice Sheets (CReSIS) radio-echo sounding (RES) data, we present a new systematic analysis for subglacial roughness beneath the Greenland Ice Sheet (GrIS)
The RES data used in this study were collected by the CReSIS over the years 1993–2016, with more-recent campaigns undertaken as part of the wider Operation IceBridge (OIB) programme
Rough beds are seen to dominate fastflowing regions, where slow-flowing regions are predominantly smooth. Whilst this relationship does not necessarily appear to conform to the classical interpretation that smooth beds are a necessary condition for fast flow, it is important to note that the length scale used in this study, at least for R (200 m), is too coarse to identify roughness information that is pertinent to basal traction and, by extension, Weertmanstyle hard-bed sliding laws
Summary
The rate of global sea-level rise contributions from the Greenland Ice Sheet (GrIS) has accelerated over the past 2 decades (Velicogna and Wahr, 2006; Rignot et al, 2011; Mottram et al, 2019); increasing rates of mass loss, driving this acceleration, are partitioned between ice discharge (over the grounding line) and, more recently, enhanced surface melt (Enderlin et al, 2014; van den Broeke et al, 2016, 2017; Hofer et al, 2017; McMillan et al, 2016; Fettweis et al, 2017; Mouginot et al, 2019; Mottram et al, 2019). To constrain projections for future change, models must parameterise characteristics influencing ice-sheet motion and dynamics In particular fast-flowing ice streams, are principally characterised by enhanced basal motion (basal sliding; Cuffey and Paterson, 2010; van der Veen, 2013). The influence of these processes on ice flow and dynamics is generally well understood Cooper et al.: Subglacial roughness of the Greenland Ice Sheet models; Cuffey and Paterson, 2010; van der Veen, 2013), it is not incorporated into ice-sheet models as spatially varying boundary conditions. Understanding the spatial variation in subglacial conditions and processes remains restricted by the paucity of observations; as such, necessary model parameters are often inverted or inferred
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