3.3.1. Modelling method

Radar power loss through the ice to the bed can be calculated from the rate of englacial attenuation, N (dBkm^–1), which is related to total ice conductivity, (Reference Winebrenner, Smith, Catania, Conway and RaymondWinebrenner and others, 2003), by

(2)

where ε is ice permittivity, ₀ is free-space permittivity and c is the speed of light in a vacuum. It has been shown (Reference MacGregor, Winebrenner, Conway, Matsuoka, Mayewski and ClowMacGregor and others, 2007, Reference MacGregor, Matsuoka, Waddington and Winebrenner2012) that a is a function of both ice temperature and chemistry, such that

(3)

where ρ_pure is the conductivity of pure ice (9.2 mS m–¹), k is Boltzmann's constant, T is ice temperature, T_r is a reference temperature (251 K), E ^H+ and E^- _ssCI are activation energies of acidity and salinity, respectively, [H+] and [ssCl^-] are acidity and salinity concentrations, respectively, and μ_H+ and μ_ssCl are molar conductivities of acidity and salinity, respectively. We see that the fundamental inputs required for deriving attenuation from the above are knowledge of ice temperature and ice chemistry throughout the ice column beneath each radar measurement. The former can be estimated from ice temperature modelling, while the required values for describing chemistry (the latter six properties in Eqn (3)) must be obtained from ice cores or otherwise inferred.

Here we use temperature output from a three-dimensional finite-difference ice-sheet model described in detail by Reference Hindmarsh and Leysinger VieliHindmarsh and others (2009), using the implementation by Reference Leysinger Vieli, Hindmarsh and SiegertLeysinger Vieli and others (2011). Using present-day geometry and balance velocities, the model provides an estimated temperature at the base and at 30 equally spaced points within the ice column. Frictional heating is included, which, together with geothermal flux, causes the calculated temperatures at the base to be at pressure-melting point. With no usable ice-core data nearby with which to constrain chemical effects, we assign values for Eqn (3) typical of those at Siple Dome, after Reference MacGregor, Winebrenner, Conway, Matsuoka, Mayewski and ClowMacGregor and others (2007) ([H+] = 2 μM, [ssCr] = 4 μM). These values are most likely transferable to the upper reaches of EIS, which lie at a similar elevation to Siple Dome and are reasonably distant from the sea, but may be less appropriate closer to the grounding line. We use them for this study, acknowledging that chemistry effects should be included (Reference MacGregor, Matsuoka, Waddington and WinebrennerMacGregor and others, 2012; Reference Matsuoka, MacGregor and PattynMatsuoka and others, 2012) but that the effect of temperature remains the predominating influence on englacial attenuation. With this in mind we caution that the relative variations in englacial attenuation across the catchment calculated with this method be treated as indicative, rather than absolute magnitudes. Finally, for other required dielectric inputs we use mean dielectric properties based on a synthesis of published results, the details of which are given by Reference MacGregor, Winebrenner, Conway, Matsuoka, Mayewski and ClowMacGregor and others (2007).

Table 1. Comparison of englacial attenuation rates and BRP mismatch between modelled and empirical approaches after correction and normalization. ‘Mean model N _bed’ is the depth-mean attenuation rate to bed using the modelled method. For the ‘Local empirical analysis’ ‘Range’ is the range of ice thicknesses over which the regression was performed, △P _geom/ △z is the gradient of the regression and N _bed is the derived depth-mean attenuation rate to bed. The ‘Maximum and minimum dP ^c’ refers to the maximum and minimum over- and underestimate of BRP using different △P _geom/ △z gradients calculated with different data subsets (i.e. all data, streaming ice only, sticky-spot profiles only, individual profiles only)

3.3.2. Empirical method

Bearing in mind the difficulties of sourcing appropriate input data for the above method, an alternative is to attempt to derive englacial attenuation using a simpler, more empirical method. The relationship between ice thickness and geometrically corrected BRP is typically quasi-linear, the least-squares gradient of which approximates to half the regional-depth-averaged attenuation rate, since path length is twice the ice thickness. Two-way attenuation to the bed can thus be estimated:

(4)

It is necessary to choose what data to include in the regression to arrive at △P _geom/ △z, and published studies have adopted a range of approaches. Reference LangleyLangley and others (2011) used a BRP/ice-thickness relationship to derive attenuation in East Antarctica, omitting data within the proposed limits of the Recovery Lakes. Also in East Antarctica, Reference Jacobel, Lapo, Stamp, Youngblood, Welch and BamberJacobel and others (2010) used the BRP/ice-thickness relationship from a large dataset (n = 464 000) after BRP measurements were normalized to those from a subglacial lake. In West Antarctica, Reference Jacobel, Welch, Osterhouse, Pettersson and MacGregorJacobel and others (2009) characterized the attenuation in distinct glaciological environments (Siple Dome, ice-stream trunk, sticky spot) using BRP/ice-thickness relationships within these areas. In order to investigate the potential for systematic scale-dependent variations in attenuation, here we compare four regressions using: (1) the complete survey which includes a range of ice from warm-based to cold-based and from slow-flowing interior ice to fast-flowing heavily deforming ice (n = 238 731); (2) only soundings within the 50 ma–¹ ice-surface velocity contour where ice is expected to be ‘streaming’ and warm-based (n = 88 833); (3) only soundings from profiles overlying sticky spots identified from basal drag inversions (n ≈ 7000; noting that profiles G-G’, H-H’, J–J' and K-K' used a 1 (is chirp pulse and were therefore not included in the regression); and (4) only local soundings from single profiles in turn (n 1000).

Values of L_bed generated by this empirical method and by the model (Section 3.3.1) suggest that the empirical method mostly generates lower L_bed (Table 1). To constrain this apparent mismatch along-track it is useful to consider the maximum relative over- and underestimation of the BRP when using empirical methods, after normalization. Data are normalized with respect to the profile BRP median and compared to the BRP profile derived with modelled englacial attenuation. The mismatch between methods, dP ^c, is defined where P _emp ^c is BRP after an attenuation correction using empirical methods, P c mod is BRP after an attenuation correction using modelled mod methods, _adj is the adjusted BRP and ^c denotes the median BRP of that profile:

(5)

(6)

5.1.1. Evaluation of attenuation methods

In this analysis we have used airborne radar data to show that, in this setting, using empirical methods to account for attenuation typically underestimates BRP relative to that which is derived using a modelling approach to attenuation. We have found that the derivation of attenuation using an empirical approach will produce highly varying values, depending on the choice and location of the radar profiles used to generate the empirical estimate. Our findings therefore support the extreme caution advised by Reference MatsuokaMatsuoka (2011) and Reference MacGregor, Matsuoka, Waddington and WinebrennerMacGregor and others (2012) with regard to using the empirical approach to derive attenuation. It is necessary, however, to consider that the modelled approach has some limitations with regard to its input data. In this study we omit the uncertainty associated with the ice dielectric property values used in the attenuation model, owing to the paucity of measurements across Antarctica (Reference MacGregor, Winebrenner, Conway, Matsuoka, Mayewski and ClowMacGregor and others, 2007). This is justified here with the emphasis that our focus is on practical interpretation-driven analysis of BRP trends in short radar profiles, rather than the derivations of absolute reflectivity across the larger region.

There are, however, cases reported from elsewhere where the empirical approach can be appropriate, and where its use offers a more efficient alternative. For example, Reference Gades, Raymond, Conway and JacobelGades and others (2000) used a profile on Siple Dome, where the ice is expected to be frozen to the bed, to derive attenuation rates in the adjacent stagnant ice streams. As attenuation is likely to be higher within stagnant ice streams, owing to the presence of warm, formerly streaming ice, any observed increase in BRP there is likely to be indicative of real changes at the ice/bed. Similarly, Reference FujitaFujita and others (2012) demonstrated that in slow-moving areas of East Antarctica a linear BRP/ice-thickness relation is found in cold-bedded areas, contrasting with a less straightforward relationship between the two in warm-bedded areas. We therefore advocate that the use of the empirical approach in estimating englacial attenuation is appropriate only for smaller areas with relatively unchanging internal properties. In this context, the empirical approach is unsuitable for estimating catchment-wide attenuation across EIS, which contains almost all major variants of ice flow, from slow-flowing and probably cold-based interior and inter-tributary regions, through a number of tributary onset regions to fast-flowing and probably warm-based tributaries and the main ice-stream trunk. It is, however, appropriate to derive local attenuation estimates for isolated analyses, provided that the ice properties and thickness do not change significantly along-track.

Using modelling rather than an empirical approach to obtain attenuation places reliance on model performance, driven in particular by the assumptions inherent within the model and the correctness of the model input. Geothermal flux and accumulation input fields are typically poorly constrained, so their effects on attenuation must be considered. Continent-wide studies of modelled englacial attenuation have shown that, in some settings, uncertainties in geothermal flux can be problematic (Reference Matsuoka, MacGregor and PattynMatsuoka and others, 2012). When basal ice is at pressure-melting point, as is the case here, errors in the geothermal flux will affect the derived melt rates but have only a minor effect on the temperature profile, from which the attenuation is derived. Errors in the accumulation field will affect the temperature profile, but mainly in the upper part of the ice column, where attenuation is relatively small. Differences between the true accumulation and that used as model input (Reference Arthern, Winebrenner and VaughanArthern and others, 2006) are probably systematic and occur on longer wavelengths than the features considered here. The steady-state model employed here does not account for transient ice temperature effects. We do not anticipate that transients are as likely in this region, given that the ice-stream tributaries are topographically confined. Moreover the slow-moving ice in this area contains well-preserved internal layering, a further indicator of its relative spatial ice-flow stability (Reference Karlsson, Rippin, Bingham and VaughanKarlsson and others, 2012).

Our attenuation model accounts for the spatially varying effect of ice temperature but neglects the potential for spatially varying ice chemistry. Impurities in ice accumulate during snowfall (wet deposition) and from atmospheric fallout (dry deposition). There is some evidence that suggests an association between radar-active acidity and salinity with accumulation and elevation, respectively (Reference Matsuoka, MacGregor and PattynMatsuoka and others, 2012). This potentially has significant implications in the Weddell Sea and Amundsen Sea sectors of West Antarctica, where high topography and accumulation coexist. However, this information remains based on a relatively small sample size and we take the view that, in the absence of more detailed parameterization of chemical variations across EIS, the better approach is not to introduce unknown complexity. A further consideration is that here we specifically limit ourselves to analysing relatively short (~20km) profiles in turn, along which we can assume that effects arising due to chemical variations are highly likely to be subordinate to those arising from temperature variation along-profile. We acknowledge, however, that further work is required to better understand the distribution of radar-active impurities on a variety of scales. Reference Wolovick, Bell and CreytsWolovick and others (2013) analysed the long (spatial) wavelength drift in high-amplitude anomalies to remove the cumulative effect of unconstrained power losses. This approach may prove useful in a larger analysis of the EIS dataset to evaluate systematic uncertainty in model-derived estimates of attenuation and BRP.

5.1.2. Additional sources of error

Radar energy can be directed away from the receiver by tilted internal layers and a strong bed slope. This effect is most apparent in profile J-J’ and is expressed as a strong negative excursion, 10 km along-track. This is the only profile associated with a steep bedrock step and the only profile which shows this feature. While topography varies in other profiles, it does so smoothly and the bed appears flat at the scale of a typical Fresnel zone (-70 m in 2 km ice; Reference Peters, Blankenship and MorsePeters and others, 2005, their Eqn (3)). Furthermore, the local drop in BRP occurs over a longer spatial scale than topographic features. Surface scattering losses (often induced by crevassing) are inferred to be important in airborne profiles across the Whillans Ice Stream shear margin (Reference Peters, Blankenship and MorsePeters and others, 2005). We do not cross any shear margins in the EIS profiles reported here and therefore do not anticipate similar losses.