Image mosaics

Clear feature geometries that are straightforward to digitize are required for mapping crevasse patterns and regional surface textures. We are interested in groups of features with similar orientations, which produce textures at the ice surface that persist over tens of km rather than finer, sub-km scale, details. While automated approaches exist (Ely and Clark, Reference Ely and Clark2016), we hand-digitize features with the intention of developing familiarity with the textures and the mechanical settings in which they are produced. These objectives make moderate resolution optical images suitable for our work.

Two image mosaics are the primary data sources for our map: the first epoch of the MODIS (Moderate Resolution Imaging Spectroradiometer) Mosaic of Antarctica (MOA; Haran and others, Reference Haran, Bohlander, Scambos and Fahnestock2005) and the Landsat Image Mosaic of Antarctica (LIMA; Bindschadler and others, Reference Bindschadler2008). The first epoch of the MOA is a composite of 260 individual MODIS images acquired between 20 November 2003 and 29 February 2004 with an effective resolution of 125 m. The LIMA, which has a resolution of 30 m and covers the ice shelf region north of about 82^° S, is a composite of nearly 1100 images acquired by the Landsat ETM+ (Enhanced Thematic Mapper Plus) sensor between 1999 and 2003. Because the MOA composite amplifies shadows, low-relief features like along-flow lineations, sagging snow bridges, and regional textures arising from snow-covered features are readily apparent in the mosaic. We thus use the MOA to make an initial mapping of the whole ice shelf surface and turn to the higher resolution LIMA and some individual Landsat 8 scenes, obtained via the USGS EarthExplorer (earthexplorer.usgs.gov), to resolve ambiguities regarding boundaries of some textured regions.

Velocity, strain rates and stresses

Glaciological strain rates and stresses, computed using remotely sensed surface velocity, are used to support interpretation of the feature maps. We compared two velocity products, the InSAR-derived MEaSUREs data set (Rignot and others, Reference Rignot, Mouginot and Scheuchl2011) and a Landsat-8-derived velocity computed by correlating grey scale patterns in small sub-scenes between sequential images collected between 1 October 2014 and 31 March 2015 (Fahnestock and others, Reference Fahnestock2016). The former covers the entire RIS, while the latter has a southern limit of 82.65^° S.

Strain rates are approximated as horizontal gradients of the two dimensional velocity field. We compute effective strain rates $ \dot {\rm \epsilon} _{\rm e}$ as the second invariant of the strain rate tensor

(1) $$ \dot {\rm \epsilon} _{\rm e}^2 = \displaystyle{1 \over 2} \dot {\rm \epsilon} _{ij} \dot {\rm \epsilon} _{ij}$$

in which the subscripts i,j represent three orthogonal directions. Vertical shearing (the vertical gradient of horizontal velocity components) is negligible in the floating ice shelf and the vertical normal strain rate is calculated from the horizontal divergence $( \dot {\rm \epsilon} _{zz} = - \dot {\rm \epsilon} _{xx} - \dot {\rm \epsilon} _{yy})$ .

Artifacts and errors in both data sets are amplified by the gradient calculation. These appear as linear features associated with image edges, circuitous shapes associated with clouds and as noise. Comparing the two effective strain rate results, we prefer the Landsat-8-derived field for its sharper and more easily managed artifacts. Uncertainty in the Landsat-8-derived velocity field is 5 m a⁻¹ and the propagated uncertainty on the effective strain rate, using gradients computed on a 750 m regular grid, is 0.008 a⁻¹. This is similar to errors reported for MEaSUREs. The estimated error does not capture noise in the effective strain rate field. The 1 − σ standard deviation in the $ \dot {\rm \epsilon}_{\rm e}$ field downstream of the large outlet glaciers discussed in a later section is 0.016 a⁻¹.

Deviatoric stresses are computed as ${\sigma} ^{\prime}_{ij} = \sigma _{ij} - (1/3)\sigma _{ij}\delta _{ij}$ in which δ _ij is the Kronecker δ. The stress tensor σ _ij is estimated using the finite strain rates ε _ij and the inverse form of the generalized flow law for ice

(2) $$\sigma _{ij} = B \dot {\rm \epsilon} _{\rm e}^{(1/n) - 1} \dot {\rm \epsilon} _{ij}$$

in which the exponent n is equal to 3. We use a value of 760 kPa a^−1/3 for the temperature-dependent rate factor B, equivalent to a depth average temperature of 247 K (Van der Veen, Reference Van der Veen1999, p. 16). Principal stress directions and magnitudes are computed as the eigenvectors and eigenvalues of deviatoric stress tensor. The uniform rate factor is very simple, but our interest is in the eigenvector directions rather than the values.

Ice surface elevation

We use the Digital Elevation Model-derived from measurements made by the Geoscience Laser Altimeter (GLAS) (DiMarzio, 2007) to supplement the discussion of ice shelf provinces. In general, thicker ice floats higher in the ocean surface but we do not convert the surface elevation into thickness because we lack knowledge of spatial variation in snow density and because this is not necessary for the intended use of the data.

Crary Ice Rise

The region around Crary Ice Rise (CIR) is complicated by its geometry and by a history of ice flow variability (Fig. 5). Upstream-pointing crevasses due to shear form narrow bands along its shorelines. Other, more prominent, textures characterize the surrounding area. Outboard of the ice rise's northern shore, a broad region characterized by transverse crevasses is associated with discharge across the grounding line of the Whillans Ice Stream (WIS) ice plain. Between these we identify a province containing ice that was once in an ice stream shear zone. Downstream, older crevasses appear to be reactivated with complicated propagation directions that imply near-field modification of the stress field due to interactions among adjacent fractures. Textures are less clear to the south of the ice rise, until the ice shears by its downstream end, generating a distinctive set of what we have called an obstacle-shear initial geometry. These crevasses persist for a long distance downstream, carried along by the ice flow.

Fig. 5. The area around Crary Ice Rise, at the dowstream end of the Whillans Ice Stream ice plain. (a) Features as observed in the MOA. (b) Digitized streaklines and crevasses, with interpreted structural provinces.

Large open rifts form near the downstream end of CIR and a narrow suture zone forms between these. Crevasses and rifts along the flanks of the suture change shape as they advect toward the shelf front and in some locations new, smaller fractures are observed between the older, larger features. These crevasses are neither uniformly distributed nor uniformly distorted and this is consistent with past disruption of discharge from WIS (Hulbe and Fahnestock, Reference Hulbe and Fahnestock2007).

Minna Bluff

An extensive set of crevasses and open rifts are produced where ice outlet glaciers flowing into the RIS turns north and shears past Minna Bluff (Fig. 6). Crevasses originating at the upstream end of the bluff cut across snow-covered crevasses that originated far upstream. The new crevasses propagate eastward until they arrest near the boundary of a province containing merged suture zones from the Skelton, Evtimov and Mulock Glaciers. As the initial crevasses round the corner and move past the bluff, a second episode of propagation develops. Secondary fractures with the appearance of exceptionally large horsetail fractures and wing cracks also form in this zone. The primary and secondary crevasses are all well aligned with principal stresses derived from the observed velocity. The crevasses eventually rotate into downstream-pointing orientations and become snow covered along the boundary between the McMurdo and Ross Ice Shelves (Whillans and Merry, Reference Whillans and Merry2001).

Fig. 6. The eastern side of Minna Bluff and adjacent RIS. (a) Digitized streaklines and crevasses, with interpreted structural provinces. (b) Detail of a Landsat 8 panchromatic band image, path 224 row 128, acquired 11/15/2016, courtesy of the US Geological Survey with Landsat-8-derived surface speed. The white star marks the approximate location of the British National Antarctic Expedition's ‘depot A’. (c) Principal stress directions and approximate magnitudes from surface velocity plotted over the Landsat 8 image. Red indicates the compressive direction and black indicates extension.

Active segments of the Minna Bluff crevasses align well with principal stress directions computed from the Landsat-8-derived velocities. Initial crevasse geometries at the upstream end of the region are aligned with the most compressive principal stress direction there. As the crevasses advect downstream, their orientations change such that the tips are poorly aligned with the stress field and secondary crevasses begin to propagate in the direction of compression. Farther downstream, snow-covered crevasses are rotated to downstream-pointing directions and experience compression orthogonal to their trace. The first direct measurement of ice shelf motion was made in this area, when members of Shackletons’ Nimrod Expedition remeasured the position of ‘depot A’, left by the 1901–1904 British National Antarctic Expedition and found it to have moved about 500 yards a^–1 (457 m a^–1) over the 6.5-year interval (Shackleton, Reference Shackleton1909; Debenham, Reference Debenham1948). The measurement was made by triangulation using the depot's original alignment with two peaks on the bluff. A remarkably similar value (425 m a^–1) is obtained from Landsat 8 image correlation.

TAM coastline between beardmore and Nimrod Glaciers

Both small and large outlet glaciers discharge ice with clearly identifiable initial crevasse patterns into the RIS along the front of the TAM. The trunks and margins of larger glaciers tend to persist as individual provinces while ice from smaller glaciers is more likely to experience texture overprinting or to merge into a suture zones as it joins the ice shelf. The coastline between Beardmore and Nimrod Glaciers provides examples of both situations and demonstrates several fates for glacier shear zones once they enter the shelf (Fig. 7).

Fig. 7. Coastline of the TAM between Beardmore and Nimrod Glaciers. (a) Features as observed in the MOA. (b) Digitized streaklines and crevasses, with interpreted structural provinces.

Ice discharging from Beardmore Glacier turns sharply north around Mount Hope as it enters the RIS. Ice from the glacier trunk is patterned by upstream-oriented linear features that appear to be the continuation of heavily crevassed flow stripes on the glacier surface. Ice from the left margin of the glacier advects downstream into a shear zone province, while on the right margin, an unknown basal obstruction disrupts the flow and produces a band of transverse crevasses in its wake. The headland of Lands End Nunataks produces a similar band of transverse crevasses. In both cases, the surface features rotate as they are advected downstream. Ice between the transverse crevasse provinces retains the surface texture indicative of margin-shear, but the features are rotated to a downstream-pointing direction.

The trunk of Lennox-King Glacier, northwest of Beardmore Glacier, is also characterized by a high discharge texture. In this case, the province associated with right lateral margin-shear persists downstream, while the left lateral margin appears to merge into a suture zone with no dominant orientation. Long shear-to-transverse crevasses form where the ice turns sharply left around Cape Maude and Driscoll Point. The crevasses emerge from the left lateral margin and arrest where their tips reach ice from the right lateral margin. Another set of transverse crevasses propagate and arrest in a similar way in ice from Robb Glacier, just southeast of Nimrod Glacier.

Provinces and deformation in the ice shelf

Because they represent different upstream deformation histories, provinces imply spatial variation in ice properties, such as crystal preferred orientation (CPO), temperature and thickness. This in turn may result in spatial variation far from the ice shelf margins (Borstad and others, Reference Borstad2012; Hudleston, Reference Hudleston2015). Ice thickness, and thus surface elevation, should be larger in bands emerging from glacier outlets than in the intervening suture zones. Strain rates should vary relatively smoothly across the ice shelf, except where across-flow variations in ice properties either promote or suppress deformation. We use effective strain rate and surface elevation to consider these possibilities in an exploratory way, focusing on the western part of the RIS where flow history is relatively simple (Fig. 8).

Fig. 8. The western side of the RIS. (a) Color map of effective strain rate plotted over the MOA, using a log scale. (b) Surface elevation plotted over the MOA. MG, Mulock Glacier; SG, Skelton Glacier; MB, Minna Bluff; RI, Ross Island.

The outlets of large TAM glaciers, such as Byrd and Nimrod Glaciers, are easily identified in the effective strain rate and surface elevation maps. The lateral margins of grounded glaciers are characterized by relatively large effective strain rates, but once the ice is afloat, the boundary that generated large shear stresses has been left behind. Fast deformation persists in some margin-shear provinces, for example, at Byrd Glacier, while it dies away in others, for example, at Nimrod Glacier. The relatively thin (low floating) suture provinces are in some cases also characterized by relatively large effective strain rates.

Byrd Glacier appears to dominate the region of the ice shelf into which it discharges. Flow traces in the floating ice remain well aligned with the grounded glacier's orientation more than 100 km downstream and the effective strain rate remains large along the margins of the high discharge province for all of that distance. Where the province begins to turn north, the fast deformation along its margins declines abruptly. It appears that ice in strongly sheared bands at the margins of the glacier continue to deform rapidly even without supporting sidewalls as long as they maintain the same alignment relative to the principal stress directions. Additional zones of relatively large deformation rate extend both left and right of the Byrd Glaicer high discharge province. The zones have a feathery appearance, with filaments of slightly larger and slightly smaller deformation rate. The effective strain rate grows again near the front of the ice shelf, in a zone comprised of the merged left and right margins of the Byrd and Mulock Glaciers.

Ice downstream from Mulock and Skelton Glaciers is characterized by patterns similar to that observed downstream of Byrd Glacier. Margin-shear and suture zone ice deforms more rapidly than ice from the glacier trunks. Initially large effective strain rates decline as the provinces turn northward into the shelf and then grow again farther downstream. Farther south along the TAM coast, ice discharging from Beardmore and Lennox-King Glaicers turns into the shelf over shorter distances and the traces of fast-deforming margins fade more quickly in the other examples, while ice in the adjacent suture zone provinces continue to deform relatively rapidly.

All together, we conclude that these relationships are evidence that material properties associated with structural provinces affect ice deformation over large distances along flow. Where the deformation rate is large, falls and then rises again in a particular zone, as downstream of Skelton, Mulock and Byrd Glaciers, we infer that ice in the zone has a CPO that is alternately well and poorly aligned for deformation in the ambient stress field. Ice in suture zone provinces is a composite of relatively thin, and fractured ice. Because the ice is thinner (floats lower), basal meltwater rising from adjacent, deeper keeled high discharge provinces, may refreeze in these zones. Where rifts have propagated through the full thickness of the ice, sea ice and marine ice may fill the open area. Thus, these provinces may be deforming relatively rapidly because the ice is thinner, warmer or does not have a CPO that makes it relatively stiff in any location or orientation to the principal stress field.