Rapid and accurate polarimetric radar measurements of ice crystal
fabric orientation at the Western Antarctic Ice Sheet (WAIS) Divide
deep ice core site

Young, Tun Jan; Martín, Carlos; Christoffersen, Poul; Schroeder, Dustin M.; Tulaczyk, S. M.; Dawson, Eliza

doi:10.5194/tc-2020-264

Cited by 6 publications

(15 citation statements)

References 56 publications

(143 reference statements)

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“…The resulting phase shift rotates the electric field and can cause polarization misalignment with linearly polarized antennas, resulting in power loss (Doake, 1981). Previous radar studies have utilized multi‐ and quadrature‐polarization setups to observe and quantify COF, and have shown good agreement with measurements from thin section analyses at coincident ice core sites (Fujita et al., 2006; Eisen et al., 2007; Ershadi et al., 2021; Dall, 2010, 2021; K. Matsuoka et al., 2003, 2009; Li et al., 2018; Jordan et al., 2019; Jordan, Besson, et al., 2020; Young et al., 2020) as well as provided evidence of more complex fabric at sites with more dynamic flow regimes (K. Matsuoka et al., 2012; Brisbourne et al., 2019; Jordan, Schroeder, et al., 2020; Jordan, Martín, et al., 2020). In‐situ observations of ice fabric have been crucial to understanding the stress patterns and behaviors of ice sheets over time and over large areas (e.g., Alley, 1988; Budd, 1972) and have provided constraints on the influence of crystal fabric on ice sheet flow (Azuma, 1994; Martín et al., 2009; Thorsteinsson et al., 2003).…”

Section: Introductionmentioning

confidence: 61%

“…(2006). Because the radar antennas were co‐linearly aligned (Table 1), we did not apply azimuthal averaging to the resulting backscatter model results, as was the case in previous power‐based analyses (K. Matsuoka et al., 2012; Brisbourne et al., 2019; Young et al., 2020). For our calculations, we used f c = 750 MHz (Arnold et al., 2020),

ε_{∥}^{'}

and

ε_{⊥}^{'}

at 3.169 and 3.134, respectively, with Δ ϵ ′ = 0.035 (T. Matsuoka et al., 1997), and a model depth and azimuthal step of 1 m and 1°, respectively.…”

Section: Methodsmentioning

confidence: 99%

“…Code used to calculate fabric asymmetry from consecutive minima was published through Young et al. (2020).…”

Section: Data Availability Statementmentioning

confidence: 99%

“…In lieu of this constraint, ice-penetrating radar has provided an alternative method to quantify bulk anisotropic COF patterns by exploiting the birefringence of polar ice, without the practical limitations of drilling (e.g., Hargreaves, 1977;Fujita et al, 2006;K. Matsuoka et al, 2012;Jordan et al, 2019;Young et al, 2020).…”

mentioning

confidence: 99%

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Inferring Ice Fabric From Birefringence Loss in Airborne Radargrams: Application to the Eastern Shear Margin of Thwaites Glacier, West Antarctica

et al. 2021

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In airborne radargrams, undulating periodic patterns in amplitude that overprint traditional radiostratigraphic layering are occasionally observed, however they have yet to be analyzed from a geophysical or glaciological perspective. We present evidence supported by theory that these depth-periodic patterns are consistent with a modulation of the received radar power due to the birefringence of polar ice, and therefore indicate the presence of bulk fabric anisotropy. Here, we investigate the periodic component of birefringence-induced radar power recorded in airborne radar data at the eastern shear margin of Thwaites Glacier and quantify the lateral variation in azimuthal fabric strength across this margin. We find the depth variability of birefringence periodicity crossing the shear margin to be a visual expression of its shear state and its development, which appears consistent with present-day ice deformation. The morphology of the birefringent patterns is centered at the location of maximum shear and observed in all cross-margin profiles, consistent with predictions of ice fabric when subjected to simple shear. The englacial fabric appears stronger inside the ice stream than outward of the shear margin. The detection of birefringent periodicity from non-polarimetric radargrams presents a novel use of subsurface radar to constrain lateral variations in fabric strength, locate present and past shear margins, and characterize the deformation history of polar ice sheets.

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Section: Introductionmentioning

confidence: 61%

ε_{∥}^{'}

and

ε_{⊥}^{'}

at 3.169 and 3.134, respectively, with Δ ϵ ′ = 0.035 (T. Matsuoka et al., 1997), and a model depth and azimuthal step of 1 m and 1°, respectively.…”

Section: Methodsmentioning

confidence: 99%

“…Code used to calculate fabric asymmetry from consecutive minima was published through Young et al. (2020).…”

Section: Data Availability Statementmentioning

confidence: 99%

mentioning

confidence: 99%

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Inferring Ice Fabric From Birefringence Loss in Airborne Radargrams: Application to the Eastern Shear Margin of Thwaites Glacier, West Antarctica

et al. 2021

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show abstract

“…The theory of radar birefringence in glaciology has long been known (Hargreaves, 1978;Woodruff and Doake, 1979;Matsuoka et al, 1997;Fujita et al, 1999), and has recently been significantly extended to exploit the capacity of phase information from newer radar systems that were previously not available (Dall, 2010;Jordan et al, 2019Jordan et al, , 2020. Examples for applications of radar polarimetry exist near ice domes in Greenland (Gillet-Chaulet et al, 2011;Jordan et al, 2019) and Antarctica (Fujita et al, 1999;Brisbourne et al, 2019), on ice rises (Drews et al, 2015;Matsuoka et al, 2015;Brisbourne et al, 2019), in flank-flow regimes (Eisen et al, 2007), divides (Young et al, 2020), and for ice streams (Robert et al, 1993;Joughin et al, 1999;Jordan et al, 2020). However, there is not yet a clear observation-based picture of how ice fabric develops across the different flow regimes.…”

Section: Introductionmentioning

confidence: 99%

Comments on tc-2020-370 by Reza Ershadi et al

2021

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Phase-sensitive radar as a tool for measuring firn compaction

Case

Kingslake

2021

J. Glaciol.

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Firn compaction models inform mass-balance estimates and paleo-climate reconstructions, but current models introduce key uncertainties. For example, models disagree on the dependence of density and compaction on accumulation rate. Observations of compaction to test these models are rare, partly because in situ methods for measuring englacial strain are time-consuming and expensive. Moreover, shallow measurements may confound strain due to compaction with strain due to ice-sheet flow. We show that phase-sensitive radio-echo sounder (pRES) systems, typically deployed to measure sub-shelf melting or ice-sheet deformation, can be used to measure firn compaction and test firn models. We present two complementary methods for extracting compaction information from pRES data, along with a method for comparing compaction models to pRES observations. The methods make different assumptions about the density structure and vary in their need for independent density measurements. Compaction profiles computed from pRES data collected on three ice rises in West Antarctica are largely consistent with measured densities and a physics-based model. With their minimal logistic requirements, new pRES systems, such as autonomous pRES, could be inexpensively deployed to monitor firn compaction more widely. Existing phase-sensitive radar data may contain compaction information even when surveys targeted other processes.

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Rapid and accurate polarimetric radar measurements of ice crystal fabric orientation at the Western Antarctic Ice Sheet (WAIS) Divide deep ice core site

Cited by 6 publications

References 56 publications

Inferring Ice Fabric From Birefringence Loss in Airborne Radargrams: Application to the Eastern Shear Margin of Thwaites Glacier, West Antarctica

Inferring Ice Fabric From Birefringence Loss in Airborne Radargrams: Application to the Eastern Shear Margin of Thwaites Glacier, West Antarctica

Comments on tc-2020-370 by Reza Ershadi et al

Phase-sensitive radar as a tool for measuring firn compaction

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