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A framework for attenuation method selection evaluated with ice-penetrating radar data at South Pole Lake (2020)

Hills, Benjamin H. ; Christianson, Knut ; Holschuh, Nicholas

Cambridge University Press

In: Annals of Glaciology. 2020; 61(81): 176-187. Published 2020 Apr 01. doi: 10.1017/aog.2020.32.

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Publication Date: 2020-04-01

Description: All radar power interpretations require a correction for attenuative losses. Moreover, radar attenuation is a proxy for ice-column properties, such as temperature and chemistry. Prior studies use either paired thermodynamic and conductivity models or the radar data themselves to calculate attenuation, but there is no standard method to do so; and, before now, there has been no robust methodological comparison. Here, we develop a framework meant to guide the implementation of empirical attenuation methods based on survey design and regional glaciological conditions. We divide the methods into the three main groups: (1) those that infer attenuation from a single reflector across many traces; (2) those that infer attenuation from multiple reflectors within one trace; and (3) those that infer attenuation by contrasting the measured power from primary and secondary reflections. To assess our framework, we introduce a new ground-based radar survey from South Pole Lake, comparing selected empirical methods to the expected attenuation from a temperature- and chemistry-dependent Arrhenius model. Based on the small surveyed area, lack of a sufficient calibration surface and low reflector relief, the attenuation methods that use multiple reflectors are most suitable at South Pole Lake.

Print ISSN: 0260-3055

Electronic ISSN: 1727-5644

Topics: Geography , Geosciences

Published by Cambridge University Press on behalf of International Glaciological Society.

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ImpDAR: an open-source impulse radar processor (2020)

Lilien, David A. ; Hills, Benjamin H. ; Driscol, Joshua ; [et al.]

Cambridge University Press

In: Annals of Glaciology. 2020; 61(81): 114-123. Published 2020 Apr 01. doi: 10.1017/aog.2020.44.

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Publication Date: 2020-04-01

Description: Despite widespread use of radio-echo sounding (RES) in glaciology and broad distribution of processed radar products, the glaciological community has no standard software for processing impulse RES data. Dependable, fast and collection-system/platform-independent processing flows could facilitate comparison between datasets and allow full utilization of large impulse RES data archives and new data. Here, we present ImpDAR, an open-source, cross-platform, impulse radar processor and interpreter, written primarily in Python. The utility of this software lies in its collection of established tools into a single, open-source framework. ImpDAR aims to provide a versatile standard that is accessible to radar-processing novices and useful to specialists. It can read data from common commercial ground-penetrating radars (GPRs) and some custom-built RES systems. It performs all the standard processing steps, including bandpass and horizontal filtering, time correction for antenna spacing, geolocation and migration. After processing data, ImpDAR's interpreter includes several plotting functions, digitization of reflecting horizons, calculation of reflector strength and export of interpreted layers. We demonstrate these capabilities on two datasets: deep (~3000 m depth) data collected with a custom (3 MHz) system in northeast Greenland and shallow (

Print ISSN: 0260-3055

Electronic ISSN: 1727-5644

Topics: Geography , Geosciences

Published by Cambridge University Press on behalf of International Glaciological Society.

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Avoiding slush for hot-point drilling of glacier boreholes (2020)

Hills, Benjamin H. ; Winebrenner, Dale P. ; Elam, W. T. ; [et al.]

Cambridge University Press

In: Annals of Glaciology. 2020; 1-5. Published 2020 Oct 12. doi: 10.1017/aog.2020.70. [early online release]

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Publication Date: 2020-10-12

Description: Water-filled boreholes in cold ice refreeze in hours to days, and prior attempts to keep them open with antifreeze resulted in a plug of slush effectively freezing the hole even faster. Thus, antifreeze as a method to stabilize hot-water boreholes has largely been abandoned. In the hot-point drilling case, no external water is added to the hole during drilling, so earlier antifreeze injection is possible while the drill continues melting downward. Here, we use a cylindrical Stefan model to explore slush formation within the parameter space representative of hot-point drilling. We find that earlier injection timing creates an opportunity to avoid slush entirely by injecting sufficient antifreeze to dissolve the hole past the drilled radius. As in the case of hot-water drilling, the alternative is to force mixing in the hole after antifreeze injection to ensure that ice refreezes onto the borehole wall instead of within the solution as slush.

Print ISSN: 0260-3055

Electronic ISSN: 1727-5644

Topics: Geography , Geosciences

Published by Cambridge University Press on behalf of International Glaciological Society.

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Measured Horizontal Temperature Gradients Constrain Heat Transfer Mechanisms in Greenland Ice (2017)

Hills, Benjamin H. ; Harper, Joel T. ; Humphrey, Neil F. ; [et al.]

American Geophysical Union

In: Geophysical Research Letters. 2017; 44(19): 9778-9785. Published 2017 Oct 05. doi: 10.1002/2017gl074917.

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Publication Date: 2017-10-05

Description: Ice in the ablation zone of the Greenland ice sheet is known to contain vertical temperature gradients that arise from conduction at the boundaries, the addition of strain and latent heat, and advective heat transport. A three-dimensional array of temperature measurements in a grid of boreholes reveals horizontal ice temperature gradients that challenge the present conceptualization of heat transfer. We measure two distinct types of temperature variability in the horizontal direction, one impacting a confined region where ice temperatures span a range of 5°C, and another with temperatures consistently varying by approximately 2°C across the entire 3-D block. We suggest the first demonstrates the localized and limited nature of latent heat input, and the second demonstrates that vertical heat advection outpaces diffusion. These findings imply that ice flow is highly variable over sub-ice-thickness length scales, which in turn generates contrasts in ice temperature that may impact ice deformation and fracturing. ©2017. American Geophysical Union. All Rights Reserved.

Print ISSN: 0094-8276

Electronic ISSN: 1944-8007

Topics: Geosciences , Physics

Published by American Geophysical Union

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Processes influencing heat transfer in the near-surface ice of Greenland's ablation zone (2018)

Hills, Benjamin H. ; Harper, Joel T. ; Meierbachtol, Toby W. ; [et al.]

Copernicus

In: The Cryosphere. 2018; 12(10): 3215-3227. Published 2018 Oct 08. doi: 10.5194/tc-12-3215-2018.

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Publication Date: 2018-10-08

Description: To assess the influence of various heat transfer processes on the thermal structure of near-surface ice in Greenland's ablation zone, we compare in situ measurements with thermal modeling experiments. A total of seven temperature strings were installed at three different field sites, each with between 17 and 32 sensors and extending up to 21 m below the ice surface. In one string, temperatures were measured every 30 min, and the record is continuous for more than 3 years. We use these measured ice temperatures to constrain our modeling experiments, focusing on four isolated processes and assessing the relative importance of each for the near-surface ice temperature: (1) the moving boundary of an ablating surface, (2) thermal insulation by snow, (3) radiative energy input, and (4) subsurface ice temperature gradients below the seasonally active near-surface layer. In addition to these four processes, transient heating events were observed in two of the temperature strings. Despite no observations of meltwater pathways to the subsurface, these heating events are likely the refreezing of liquid water below 5–10 m of cold ice. Together with subsurface refreezing, the five heat transfer mechanisms presented here account for measured differences of up to 3 ∘C between the mean annual air temperature and the ice temperature at the depth where annual temperature variability is dissipated. Thus, in Greenland's ablation zone, the mean annual air temperature is not a reliable predictor of the near-surface ice temperature, as is commonly assumed.

Print ISSN: 1994-0416

Electronic ISSN: 1994-0424

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Processes influencing near-surface heat transfer in Greenland's ablation zone (2018)

Hills, Benjamin H. ; Harper, Joel T. ; Meierbachtol, Toby W. ; [et al.]

Copernicus

In: The Cryosphere Discussions. 2018; 1-22. Published 2018 May 02. doi: 10.5194/tc-2018-51. [early online release]

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Publication Date: 2018-05-02

Description: To assess the influence of various mechanisms of heat transfer on the near-surface ice of Greenland's ablation zone, we incorporate highly resolved measurements of ice temperature into thermal modeling experiments. Seven separate temperature strings were installed at three different field sites, each with between 17 and 32 sensors and extending up to 20m below the surface. In one string, temperatures were measured every 30 minutes, and the record is continuous for more than three years. We use these measured ice temperatures to constrain modeling analyses focused on four isolated processes to assess the relative importance of each to the near-surface ice temperature: 1) the moving boundary of an ablating surface, 2) thermal insulation by snow, 3) radiative energy input, and 4) temperature gradients below the seasonally active near-surface layer. In addition to these four processes, transient heating events were observed in two of the temperature strings. Despite no observations of meltwater pathways to the subsurface, these heating events are likely the refreezing of liquid water below 5–10m of cold ice. Together with subsurface refreezing, the five heat transfer mechanisms presented here account for measured differences of up to 3°C between the ice temperature at the depth where annual temperature variability is dissipated and the mean annual air temperature. Thus, in Greenland's ablation zone, the mean annual air temperature cannot be used to predict the near-surface ice temperature, as is commonly assumed.

Print ISSN: 1994-0432

Electronic ISSN: 1994-0440

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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