Thinning rates of ice shelves vary widely around Antarctica, and basal
melting is a major component of ice shelf mass loss. In this study, we
present records of basal melting at a unique spatial and temporal resolution
for East Antarctica, derived from autonomous phase-sensitive radars. These
records show spatial and temporal variations of basal melting in 2017 and
2018 at Nivlisen, an ice shelf in central Dronning Maud Land. The annually
averaged basal melt rates are in general moderate (∼0.8 m yr-1).
Radar profiling of the ice shelf shows variable ice thickness from smooth
beds to basal crevasses and channels. The highest basal melt rates (3.9 m yr-1) were observed close to a grounded feature near the ice shelf front. Daily time-varying measurements reveal a seasonal melt signal 4 km
from the ice shelf front, at an ice draft of 130 m, where the highest daily
basal melt rates occurred in summer (up to 5.6 m yr-1). In comparison
with wind, air temperatures, and sea ice cover from reanalysis and satellite
data, the seasonality in basal melt rates indicates that summer-warmed ocean
surface water was pushed by wind beneath the ice shelf front. We observed a
different melt regime 35 km into the ice shelf cavity, at an ice draft of
280 m, with considerably lower basal melt rates (annual average of 0.4 m yr-1) and no seasonality. We conclude that warm deep-ocean water at
present has a limited effect on the basal melting of Nivlisen. On the other
hand, a warming in surface waters, as a result of diminishing sea ice cover,
has the potential to increase basal melting near the ice shelf front.
Continuous in situ monitoring of Antarctic ice shelves is needed to
understand the complex mechanisms involved in ice shelf–ocean
interactions.
Introduction
The Antarctic contribution to global sea level rise has increased by a
factor of 5 in the past two decades (IMBIE Team, 2018). Over 80 %
of the grounded ice in Antarctica drains out into floating ice shelves
(Dupont and Alley, 2005). The thinning rates of these ice shelves vary
widely around the continent (Paolo et al., 2015). The mass balance of an ice
shelf is the sum of the ice gain and loss; ice gain comprises the advective
input from ice across the grounding zone (where ice detaches from the bed
and becomes afloat), snow accumulation, and marine-ice accretion. Ice loss
encompasses surface melting and sublimation, basal melting from the ocean
underneath the floating ice shelf, and iceberg calving at the ice front
(Bamber et al., 2018). A negative mass balance can affect ice shelf
stability, where a net mass loss reduces back stresses on grounded ice
upstream, leading the tributaries to flow faster (Reese et al., 2018).
Understanding controls on the mass balance of ice shelves around Antarctica
is therefore the key to gaining a better understanding of the continent's
present and future contribution to global sea level rise.
Iceberg calving occurs irregularly in time and can have dramatic effects on
ice shelf mass balance when it occurs (Hogg and Gudmundsson, 2017). At
present, iceberg calving comprises approximately half of the mass loss from
the Antarctic Ice Sheet, while the other half comes from basal melting
(Depoorter et al., 2013; Rignot et al., 2013). Basal melting is not uniform
and depends on the ocean properties in the vicinity of the ice shelf and the
topography of both the ocean bed and the ice shelf base. Jacobs et al. (1992) described how different water masses can melt the ice shelf from
below.
In mode 1, ocean water with temperatures at the surface freezing point
provides heat for melting deeper parts of the ice base because the
pressure melting point of the ice is decreased to lower temperatures at
depth. Basal melting at the deep grounding zones can be high and often occur
at basal channels (e.g. 22 m yr-1 for Ross Ice Shelf; Marsh et al.,
2016); however, substantial marine-ice accretion reduces the net melting
below these large ice shelves when the rising melt plume from the grounding
zone super-cools and refreezes on the ice shelf base at shallower depths
(Joughin and Vaughan, 2004). Since these cold shelf waters provide a limited
source of ocean heat (Darelius and Sallée, 2017), average basal melt
rates are often low for the largest ice shelves (e.g. 0.3 m yr-1 for Ronne Ice Shelf; Rignot et al., 2013).
In mode 2, ice shelves melt from the presence of warm circumpolar deep-water
intrusion (Jacobs et al., 1992). The rapid retreat and high thinning rates
of glaciers in Antarctica have been attributed to the presence of warm
circumpolar deep water below ice shelves in the Amundsen Sea sector of West
Antarctica (Pritchard et al., 2012; Rignot et al., 2013). Circumpolar deep
water surrounds the Antarctic continent, flowing clockwise with the
Antarctic Circumpolar Current and is abundant near the continental shelf of
West Antarctica. Circumpolar deep water accesses the deep bases of ice
shelves directly through cross-continental submarine troughs, causing the
higher basal melt rates; for example, Rignot et al. (2013) found Pine Island
Ice Shelf to have an average melt rate of 16 m yr-1. In East
Antarctica, basal melting has been linked to circumpolar deep-water
intrusion only at Totten Ice Shelf, where annual basal melt rates reached
∼11 m yr-1 (Rignot et al., 2013; Rintoul et al., 2016). Farther
west, in the Weddell Sea sector a cooler modified version of circumpolar
deep water is advected along the coast (Dong et al., 2016; Ryan et al.,
2016).
In mode 3, ice shelves can melt at shallow depths in the vicinity of their
ice fronts when summer-warmed surface water is pushed by wind and tides
under ice shelves (Jenkins and Doake, 1991; Makinson and Nicholls, 1999;
Sverdrup, 1954; Zhou et al., 2014). Antarctic surface water has been
observed under Ross Ice Shelf in West Antarctica (Malyarenko et al.,
2019; Stern et al., 2013; Stewart et al., 2019) and at Fimbulisen in East
Antarctica (Hattermann et al., 2012), suggesting it may be a more important
process in basal melting than previously thought. Spatial patterns and
relative magnitudes of all these three modes of basal melting remain largely
unknown. Numerical modelling, however, indicates that the response of basal
melting in the future strongly depends on the surface air warming (Kusahara
and Hasumi, 2013). Future basal melting in Antarctica will therefore reflect
the integrated response to changes in circumpolar deep-water temperatures
and coastal processes that control its access to the continental shelf
(Thompson et al., 2018). The detailed interplay of these processes today and
in a future climate is still a major source of uncertainty when evaluating
the response of the Antarctic Ice Sheet to climate change (Adusumilli et
al., 2018).
In this study, we measured basal melting at Nivlisen (70∘ S,
12∘ E) in central Dronning Maud Land, East Antarctica, using
autonomous phase-sensitive radio echo sounders (ApRES; Fig. 1).
Phase-sensitive radars use a technique where the phase of individual
internal ice reflectors is tracked, yielding a time series of ice thickness
change with high accuracy (∼1 mm) and short time intervals (Corr et al.,
2002; Nicholls et al., 2015). This technique has been used to measure basal
and englacial properties of ice at several locations around Antarctica
(e.g. Davis et al., 2018; Jenkins et al., 2006; Marsh et al., 2016; Stewart
et al., 2019) and in Greenland (Vaňková et al., 2018). Our objective
is to study the spatial and temporal variations of basal melting and to
interpret the results using (1) radar profiles of ice thickness, (2) in
situ measured and satellite-derived or modelled ice flow speed and surface
mass balance, and (3) atmospheric forcing from reanalysis data, sea ice
distribution, and ocean tides. The data imply that different modes of basal
melting are present at Nivlisen. Our in situ measured data of basal melting
complement satellite-derived maps of spatially smoothed time-averaged basal
melt rates, and these will be a valuable data source for the validation of ice shelf
and ocean models.
Study area. (a) Dronning Maud Land coast, with
research stations (Troll and Maitri), ice shelves (light blue), and
elevation contours with bathymetric features (Arndt et al., 2013).
(b) Nivlisen with surrounding areas. Study sites, where
ApRES and stakes for ice velocity and surface mass balance were located,
ApRES overwintering sites (no. 1 called “seaward” and no. 2 called
“landward”), and low-frequency radar profiles (A, B, and C). Satellite-derived ice speed (Rignot et al., 2011), surface elevation (m a.s.l.; Howat
et al., 2019), grounding line, ice shelf front (Mouginot et al., 2017), and
ice structure (Goel et al., 2019) are also shown. Background image is
Landsat image mosaic with sea ice in front of the ice shelf (Bindschadler et
al., 2008). Grid coordinate system is WGS-84.
Study area
Dronning Maud Land covers a large area of East Antarctica, and its 2000 km long coast is characterized by extensive ice shelves interspersed with
numerous ice rises and rumples (Fig. 1a). Ice rises are locations where the
ice shelf flow is diverted around the grounded ice, and they are miniature ice
caps with their own flow fields from the summit (Matsuoka et al., 2015). Ice
rumples are smaller features that impose a disturbance on the ice shelf
flow, causing the ice to thicken upstream with extensive crevassing.
Individual ice shelves are relatively small, but they extend close to, or even
beyond, the continental shelf break (Heywood et al., 1998). Basal melt rates
from satellite data in Dronning Maud Land vary from nearly 0 to 7 m yr-1 (2003 to 2008; Rignot et al., 2013). The interior of this region
is partly separated by high mountains, causing steep ice surface slopes from
the continental plateau towards the coastal areas (Howat et al., 2019). The
drainage basin of Nivlisen (27 700 km2), including the grounded ice
that drains to the ice shelf, has an estimated potential of raising global
sea level by 8 cm (Rignot et al., 2019).
Nivlisen has an areal extent of ∼7300 km2 and forms a closed
embayment between two larger promontory-type ice rises, Djupranen and
Leningradkollen (Fig. 1b). Such grounded features are known to play vital
roles in ice shelf and ice sheet dynamics over various timescales. For
example, the un-grounding of an ice rumple within the ice shelves of Pine Island Glacier
and Thwaites Glacier is thought to be a major cause of the ongoing rapid
retreat and thinning (Favier et al., 2012; Gladstone et al., 2012; Jenkins
et al., 2010). Bawden Ice Rise near the edge of Larsen C Ice Shelf helps
maintain its stability, despite the collapse of the neighbouring Larsen A and B
ice shelves (Borstad et al., 2013; Holland et al., 2015). Nivlisen is also
grounded at a series of smaller ice rises and rumples near the present ice
front, as well as at a few ice rumples in the middle of the ice shelf
(Moholdt and Matsuoka, 2015). The bathymetry under the ice shelf is unknown.
The average ice shelf flow speed is 80 m yr-1 (Rignot et al., 2011).
Potsdam Glacier drains into Nivlisen from the southeast, with an average ice
thickness of ∼1000 m (Fretwell et al., 2013) and ice flow speed of
∼50 m yr-1 (Anschütz et al., 2007; Rignot et al., 2011). The
satellite-derived estimate of the grounding line flux for Nivlisen was 3.9±0.8 Gt yr-1 (2007–2008; Rignot et al., 2013). Elevated
topography of the ice rises causes highly variable local climate and surface
mass balance gradients (Lenaerts et al., 2014). In addition, Nivlisen has
large surface mass balance transitions from being positive in the firn area
near the ice front to being negative in the blue-ice area near the grounding
zone, with increased wind erosion, evaporation, and sublimation owing to
katabatic winds (Horwath et al., 2006). Near the grounding zone, summer
surface melting is sufficient to form supraglacial lakes and streams that
may occasionally drain through the ice shelf (Kingslake et al., 2015),
making Nivlisen potentially sensitive to hydrofracturing (Lenaerts et al.,
2017). Rignot et al. (2013) estimated the surface mass balance to be 1.8±0.3 Gt yr-1 (average 1979–2010) and the average calving flux
to be 1.3±0.4 Gt yr-1 (2007–2008). These numbers together
with the grounding line flux mentioned earlier and a slightly positive net
mass balance of 0.6 Gt yr-1 (2003–2008) result in a residual net
basal melt of 3.9 Gt yr-1 or an average basal melt rate of 0.5±0.2 m yr-1 (Rignot et al., 2013). Thus, basal melting comprises ∼75 % of the total outgoing flux, with the residual ∼25 %
attributed to iceberg calving.
The continental shelf extends ∼100 km north of Nivlisen into the
Lazarev Sea, and it is roughly 500 m deep (Arndt et al., 2013; Fig. 1a). Carbon
dating of laminated sediments at several locations near the ice shelf
suggests that the ice front retreated to its present position
∼11 kyr ago (Gingele et al., 1997). North of Nivlisen lies
Astrid Ridge (Fig. 1a), an undersea bathymetric feature extending from the
Antarctic margin northward to ∼65∘ S. Farther east
lies Gunnerus Ridge (Fig. 1a), where circumpolar deep water is entrained
into the Antarctic slope current. The circumpolar deep water is then cooled
and modified to become warm deep water (Dong et al., 2016; Ryan et al.,
2016) and flows westward along the continental slope before finally
entraining into the Weddell Gyre. The ice shelf cavities in this region are
separated from warm deep water by the Antarctic slope front, which is a
pronounced transition zone over the narrow continental shelf between eastern
shelf water and warm deep water. The slope front is mainly attributed to
coastal downwelling caused by the prevailing easterly winds (Sverdrup, 1954;
Thompson et al., 2018). The coastal dynamics that set the warm deep-water
depth along the continental shelf break involves the balance between
wind-driven Ekman overturning and counteracting eddy fluxes (Nøst et al.,
2011; Thompson et al., 2014). These processes respond to changes in wind and
buoyancy fluxes (Hattermann et al., 2014; Stewart and Thompson, 2016),
including self-amplifying feedbacks of increased fresh-water input from
increased basal melting (Hattermann, 2018).
The Southern Ocean, including the Weddell Sea, has warmed over recent
decades (Gille, 2002; Schmidtko et al., 2014) with the changes driven
primarily by anthropogenic climate warming (Swart et al., 2018). Sea ice cover has increased slightly since 1979 around Antarctica in general (De
Santis et al., 2017); however extreme changes have occurred in recent years
with record maxima 3 years in a row (2012 to 2014), followed by record
minima in 2016 and 2017 (Shepherd et al., 2018; Stuecker et al., 2017; Turner
et al., 2015). Sea ice fluctuations are strongly correlated with the
dominant trends in Southern Hemisphere climate variability (Kwok et al.,
2016; Kwok and Comiso, 2002), although further studies are needed to
understand the drivers behind these fluctuations (Turner and Comiso, 2017). An increase
in the seasonality of the easterly winds has been observed (Hazel and
Stewart, 2019), and this may affect the formation and export of sea ice and
the transport of surface waters and warm deep water to the continental
shelf. All these pan-Antarctic observations may affect ocean water flow and consequent ice shelf thinning in Dronning Maud Land, but the consequences remain largely unknown.
Data and methods
We conducted three field campaigns on Nivlisen and adjacent ice rises during
the Antarctic austral summers, from mid-November until the end of December 2016
to 2018, with logistic support from the Indian Maitri and Norwegian Troll
Station (Fig. 1a). In December 2016, we installed stakes for the measurement of
ice velocity and surface mass balance at 29 locations on Nivlisen and
measured the ice thickness with an ApRES system (200–400 MHz), developed
by the British Antarctic Survey (British Antarctic Survey, 2018; Nicholls et
al., 2015; Fig. 1b): (1) 13 stakes were placed across the ice flow with a
spacing of 10 km (profile A); (2) 10 stakes were placed along the ice flow
towards a grounded ice rumple near the ice front with a spacing of 1 to 4 km
(profile B); and (3) 4 stakes were placed along the ice flow towards the
ice front with a spacing of 10 km (profile C). We also measured the ice shelf
thickness and basal structure with a low-frequency (5 MHz) radio echo
sounder along these three profiles. After the initial measurements, we
installed similar ApRES systems at two locations for hourly measurements of
basal melting and strain rates over the winter, each powered by a 12 V 114 Ah battery (Fig. 1b): (1) one 4 km from the ice shelf front, called the
“seaward site” hereafter, and (2) the other 35 km from the ice shelf front, called
the “landward site”. In December 2017 and 2018, we revisited and
remeasured all ApRES sites to get averaged annual values of basal melting
and strain rates and retrieved the time series data from the two
overwintering stations. Extensive crevassing prevented the three sites
closest to the ice rumple (profile B, Fig. 1b) from being revisited in 2018.
Autonomous phase-sensitive radio echo sounder
ApRES uses the frequency-modulated continuous wave (FMCW) technique (Rahman,
2016). The instrument transmits a signal sweeping from 200 to 400 MHz over a
period of 1 s to form a chirp (Nicholls et al., 2015). This is a
low-power consumption system, with the power to the transmitter antenna totalling 100 mW. The averaged signal was amplified and de-ramped, a process where the
received signal is mixed with a replica of the transmitted signal to extract
differences in frequencies. The de-ramped signal was then filtered to
amplify the higher frequencies preferentially, which enhanced weaker signals
from more distant reflectors. Each sample consisted of 100 chirps, collected
over a period of a few minutes. The data were digitized and stored on secure
digital cards for further processing.
We processed the data following Brennan et al. (2014) and Nicholls et al. (2015). The data were Fourier transformed to give a complex signal amplitude
as a function of delay time (or depth) assuming a constant propagation
velocity of 168 m µs-1. An amplitude cross correlation between the
two returns, for a depth range within the firn layer (typically from 40 to
70 m), provided a vertical shift that approximately accounted for snow
accumulation between the visits. The displacement of the reflectors between
the two visits was then plotted as a function of depth (Supplement Fig. S1a). To give the necessary depth resolution, the phase of the signals was
used to calculate the displacements by cross-correlating 4 m segments of the
first profile with the complex conjugate of the corresponding segment of the
second. Under the assumption of a constant vertical strain rate between the
bottom of the firn layer and just above the ice base, we fit a straight line
to the layer displacements. The correction for snow accumulation between the
two visits included the coarse correction mentioned above and the precise
correction inherent in the phase processing. This effect, together with the
effect of the non-linear (with depth) displacements due to firn compaction,
was contained within the intercept at the vertical axis. Thus the basal
melt was given by the deviation of the displacement of the basal reflection
from the straight line fit (Supplement Fig. S1b). The error in the
calculated strain was estimated using the quality of fit of the linear
regression. The uncertainty in the melt rate was obtained by combining the
uncertainty in the strain rate with the uncertainty in the change in the
range to the basal reflector, deduced from the signal-to-noise ratios of the
two basal reflections.
To calculate the hourly melt rate time series for the two overwintering
sites (Fig. 1b), we tracked the basal reflector using phase-coherent
processing. This allowed us to determine the speed of motion of the ice base
with respect to the antenna, which we hereafter call the thinning rate. To
remove the component of ice column vertical strain rate caused by tidal
variations, we filtered the basal vertical speeds with a 36 h low-pass
filter. We then removed an annual average vertical strain rate from the
filtered basal motion, resulting in net basal melt rates. We assumed that,
at periods longer than 36 h, the variability in strain rate is small
compared with the variability in basal melt rate.
Low-frequency radar profiling
We collected ∼180 km of continuous radio echo sounding profiles on
Nivlisen to measure ice thickness and englacial and basal structure
(profiles A, B, and C; Fig. 1b). We used a common-offset impulse radar
system (Dowdeswell and Evans, 2004) based on the radar developed by Matsuoka
et al. (2012) and processing steps following Lindbäck et al. (2014). We
used half-wavelength dipole antennas with a 5 MHz centre frequency, using a
Kentech impulse transmitter with an average output power of 35 W. The
transmitter and receiver systems were mounted on two sleds and towed behind
a snowmobile at a speed of ∼10 km h-1. We positioned the
measurements using data from a code phase Global Positioning System (GPS)
receiver mounted on the radar receiver box 20 m in front of the common
mid-point of the antennas along the travelled trajectory of the snowmobile.
We post-corrected the height using the Canadian precise point-processing
service (CSRS-PPP; Natural Resources Canada, 2017) from a kinematic
carrier phase dual-frequency GPS receiver mounted on the snowmobile. The
radar measurements had an average trace spacing of ∼5 m.
Several corrections and filters were applied to the radar data: (1) dewow
and bandpass filters to remove unwanted frequency components in the data,
(2) a depth-variable gain function, and (3) a normal move-out correction to
correct for antenna separation, including adjusted travel times for the
trigger delay. The basal returns were digitized semiautomatically with a
cross-correlation picker at the first break of the bed reflection (Irving et
al., 2007). We calculated ice thickness from the picked travel times of the
bed return using a constant radio wave velocity of 168 mµs-1
for ice. We added a correction term of 2 m to account for the faster
propagation in the firn. The firn had a depth of ∼50 m, derived from
the ApRES internal reflectors (Supplement Fig. S1c). To show the depth of
the base of the ice shelf in the water column, we calculated the ice draft
from the ice thickness by subtracting the surface elevation, using an
EIGEN-6C4 mean geoid height of 17 m above the ellipsoid (Förste et al.,
2014). We estimated the error in ice thickness by standard analytical error
propagation methods (Lapazaran et al., 2016; Taylor, 1996) outlined in
Lindbäck et al. (2018). The estimation included the error in the radar
acquisition and horizontal positioning error, where the radar acquisition
errors comprised errors in radio wave velocity and two-way travel time.
Velocity can vary spatially, depending mainly on density. Errors in two-way
travel time were estimated to be the range resolution, which is the accuracy
of the measurement of the distance between the antenna and the bed. The
average radar system error was estimated to 13.3±1.2 m. The surface
and base of the ice shelf is relatively flat, giving very small vertical
errors from horizontal positioning (0.1±0.2 m). The total error in
ice thickness is presented together with the data in Sect. 4.
Ice flow and surface mass balance from stakes
Stake height over the surface was measured manually, and stake position was
measured for 15 min using carrier phase dual-frequency GPS receivers at a
1 s logging interval. The stakes were revisited and measured in December
2017 and 2018. We processed the positions statically using CSRS-PPP (Natural
Resources Canada, 2017). Snow density was measured at five locations on
Nivlisen with an auger drill to a depth of 3 m and varied from 430 to 450 kg m-3. We used the average snow density of 440 kg m-3 and an ice
density of 917 kg m-3 to calculate the surface mass balance in metres ice equivalent. Ice flow velocity and surface mass balance were compared with
estimates from satellite data (Rignot et al., 2011) and regional atmospheric
modelling (van de Berg et al., 2006).
Results
In 2017, averaged annual basal melt rates, at 29 ApRES sites on Nivlisen
(Fig. 1b), ranged from 0.12±0.06 to 3.94±0.04 m yr-1
(Figs. 2a and 3), with a median value of 0.80 m yr-1. The highest
averaged annual basal melt rates were observed just upstream of an ice
rumple at the ice front. The lowest melt rates were observed in the central
and eastern parts of the ice shelf. In 2018, averaged annual basal melt
rates at 26 sites ranged from 0.13±0.06 to 1.48±0.01 m yr-1 (Supplement Fig. S2). In 2018, the median melt rate was 0.72 m yr-1. Basal melt rates were slightly lower in the second year at 18
sites and slightly higher for 8 sites. The measurements in 2018 excluded
three sites closest to the ice rumple, which had the highest melt rates in
2017, since we were not able to revisit these sites because of many
crevasses in the area. Errors in basal melt rates were on average 0.023 m yr-1 in 2017 and 0.025 m yr-1 in 2018.
Comparison between in situ measured and satellite-derived
or modelled values. (a) ApRES-derived averaged annual basal melt
rates. See Supplement Fig. S2 for averaged annual basal melt rates for
2018, which is on average within ±10 % of the 2017 values.
(b) Ice thickness from the Bedmap2 product (grid and contour lines;
Fretwell et al., 2013) and difference to low-frequency radar profiles
(satellite derived minus measured in point colour). (c) Ice flow
speed from stakes (point numbers) and gridded satellite values (Rignot et
al., 2011). Differences (satellite derived minus measured) are shown in point
colour. (d) Surface mass balance (SMB) from stakes (point numbers)
and gridded modelled values (van de Berg et al., 2006). Differences (modelled
minus measured) are shown in point colour. Background image and contour
lines are the same as in Fig. 1.
Profiles of low-frequency radar, ice surface elevation,
basal melt, and strain (locations in Fig. 1b): A–A′ across ice flow from
west to east (125 km), B–B′ along ice flow from south to north towards an
ice rumple (16 km), and C–C′ along ice flow from south to north towards
the ice front (32 km). Sub-panels show (a) radar profiles with
surface elevation (blue line), englacial stratigraphy, and basal elevation
(grey-tone shading), and locations of ApRES measurements (black vertical
lines), (b) surface elevation from carrier phase kinematic GPS
measurements, and (c) annual basal melt rate (red) and vertical
strain rates (black dashed line equal 0) for 2017. Note that the x axis scales
vary between the three profiles.
Strain rates had a median annual value of -4.7×10-4 yr-1 in
2017 and -4.6×10-4 yr-1 in 2018. The vertical strain rate
contribution to the change of the average rate of thickness was 22 % on average.
The errors in strain were low, on average 6.2×10-5 yr-1 in
2017 and 7.1×10-5 yr-1 in 2018. For most parts of the ice
shelf the strain rates were negative, meaning that the ice was thinning by
longitudinal stretching; however, close to the ice rumple mentioned earlier
(profile B; Fig. 3) we observed a transition from negative to positive
strain rates (from -5.4×10-4 to 2.2×10-2 yr-1), with
increasing compressional thickening of the ice towards the ice rumple.
Positive strain rates were also observed for five sites 5–10 km upstream
of the larger ice rises in the central and in the eastern part of the ice
shelf (profile A; Fig. 3), indicating a far-reaching buttressing effect
(distance up to ∼30 ice thicknesses from the ice rises).
The two overwintering ApRES systems were used to derive a time series of basal
melt rates. The seaward overwintering site was located 4 km from the ice
front and had an ice draft of 130 m, as measured with low-frequency radar.
It operated for 14 months (from 11 December 2016 to 4 February 2018) before the battery
failed. At this site 36 h low-pass filtered basal melt rates
varied from ∼0 to 5.6 m yr-1, where the highest melt rates
occurred in summer (29 January 2017; Fig. 4a). The landward overwintering site
was located 35 km from the ice front and had an ice draft of 280 m. The data
cover 22 months (from 4 January 2017 to 27 November 2018), excluding December 2017
when the instrument was used for measuring annual basal melt rates at other
sites. At this site, 36 h low-pass filtered basal melt rates varied from
∼0 to 2.0 m yr-1, where the highest melt rates occurred in winter (12 June 2018; Fig. 5a).
Basal melt and thinning rates for the seaward
overwintering site, with variations on timescales of (a) months
(11 December 2016–4 February 2018), (c) weeks (4 January–1 May 2017), and
(d) days (1–31 January 2017). The dashed black line in (d) is the
unfiltered raw data with a thickness change including strain rates.
(b) Continuous wavelet transform of the normalized thinning to
identify the dominant modes of variability at different timescales. The
left axis is the Fourier period. The colour shading represents the thinning
associated with fluctuations over the course of the year with a particular
time period (yellow indicates high power, blue indicates low power). The black contours
delimit significant modes of variance at 95 % against red noise. Within
the cone of influence, shown as a lighter shade in the right and left lower
corners, edge effects may distort the image. Dashed white lines show the
periods of major tidal constituents (0.5 d ≈K1, 1 d ≈M2/S2, and 14 d ≈Mf).
Basal melt and thinning rates for the landward
overwintering site, with variations on timescales of (a) months (4 January 2017–27 November 2018), (c) weeks (4 January–1 May 2017), and
(d) days (4–31 January 2017). (b) Continuous wavelet
transform of the normalized thinning to identify the dominant modes of
variability at different timescales. The grey box masks a time period with no
data. See Fig. 4 caption for more information.
Ice thickness, measured with low-frequency radar along profiles A, B, and C
(Fig. 1b), varied from 160 to 330 m (Fig. 2b), with a median value of 260 m.
We observed the thinnest ice close to the ice front along profile C (Fig. 3),
and the thickest ice was in the southernmost part of the ice shelf along the
same profile. The total error in ice thickness along the profiles, including
radar system and positioning errors, varied between 10.6 and 15.7 m. The
broad thickness pattern agrees with the gridded ice thickness from the Bedmap2 data suite
(Fretwell et al., 2013), except close to the ice front in the western part
(profile C), where the thickness of Bedmap2 is clearly too high (Fig. 2b),
possibly due to errors in the input data or the interpolation between them.
Ice draft varied from 120 to 280 m with a median value of 220 m (Fig. 3). We
observed no significant relation between basal melting and ice draft.
Several locations with undulating englacial layers, basal channels, and
crevasses were visible in the radar profiles (Fig. 3). Stake-measured ice
flow speeds varied from 13 to 113 m yr-1 in 2017, with an average value
of 80 m yr-1, agreeing with satellite estimates (Rignot et al., 2011;
Fig. 2c). Surface mass balance values varied between 0.12 and 0.62 m i.e. yr-1 in 2017 with an average of 0.45 i.e. yr-1, higher than the
modelled average estimates of 0.2 m i.e. yr-1 (van de Berg et al.,
2006), but they had the same spatial pattern (Fig. 2d).
Discussion
In the following sections, we discuss the spatial and temporal variations in
basal melting and compare our results with other studies from Antarctica.
For each section, we also discuss strengths, limitations, and
recommendations for future studies.
Spatial variations in melting
On Nivlisen, we observed the highest averaged annual basal melt rates (3.9 m yr-1) close to a small (4.2 km2) ice rumple at the ice front (Figs. 2a and 3). Similar basal melt rates (∼4 m yr-1) were
inferred from satellite data near Bawden Ice Rise in the Antarctic
Peninsula (Adusumilli et al., 2018). In modelling experiments, locally
enhanced basal melt rates were caused by strong tidal currents in shallow
regions (thin water column thickness) around the ice rise that increased the
ice–ocean heat exchange (Mueller et al., 2012). At Nivlisen, we have no
observations of ocean currents near the ice rumple, but the bathymetry must
be shallow since the ice shelf grounds in this region. Ice shelf thinning
could potentially increase the water column thickness, leading to a negative
(stabilizing) feedback on the melting by reducing the ocean currents
(Mueller et al., 2012, 2018; Padman et al., 2018). In terms of ice thickness
change, the observed thinning from the basal melt is compensated by a
positive vertical strain that implies compressional thickening towards the
ice rumple (up to 4 m yr-1). Thicker ice towards the ice rumple
indicates a buttressing effect on the ice shelf (profile B; Fig. 3). We
observed many crevasses in this region that made it, for safety reasons,
difficult to revisit the three closest sites during the third field season
(December 2018). Many ice shelves like Nivlisen are stabilized by pinning points
at their ice fronts, which may be sensitive areas for future change. The
effects of future increased basal melting at the Nivlisen ice rumple are
uncertain, and modelling work may indicate whether un-grounding of the ice
would potentially lead to substantial loss of buttressing (Borstad et al.,
2013).
Estimates of basal melt rates for Dronning Maud Land ice shelves have mainly
used satellite techniques, modelling, or limited spatial or temporal
coverage of in situ radar observations (Berger et al., 2017; Langley et al.,
2014b). Fimbulisen is situated 400 km west of Nivlisen (Fig. 1a) at the
outlet of Jutulstraumen, one of the largest ice streams in Dronning Maud
Land. Below the deep keel from Jutulstraumen (300–400 m ice draft),
time-averaged basal melt rates of several metres per year were observed,
whereas at the shallower parts of the ice shelf (200–300 m ice draft),
lower melt rates were observed (Langley et al., 2014a). In addition,
annual average basal melt rates were modelled to be near zero for large
areas (Hattermann et al., 2014). Hattermann et al. (2014) hypothesized that
basal melting (melt mode 1, Sect. 1) occurred at the deepest parts of
Fimbulisen (below ice drafts of 400 m). The rising melt plume caused marine
accretion at shallower depths closer to the ice front, which together with
seasonal melting from summer-heated surface water (melt mode 3, Sect. 1),
resulted in the low net basal melt rates. The seasonal marine-ice formation
was inferred from an ice shelf cavity mooring (Hattermann et al., 2012).
Nivlisen is in comparison relatively thin (Fig. 2b), and we have no melt
observations from the thicker ice in the southern areas. Grounding line ice
drafts (Fig. 1b) derived from Fretwell et al. (2013) and Mouginot et al. (2017) have an average value of 350 m. The deepest part of the grounding
line (630±100 m) is located at the outflow of Potsdam Glacier (Fig. 1b), where higher basal melt rates may occur. In addition, Nivlisen has
three ice front sections, separated by ice rises and ice rumples, where the
ocean can gain access to the inner parts of the ice shelf cavity. At
Fimbulisen, Hattermann et al. (2012, 2014) found that a portion of the
westward flowing coastal current was diverted under the ice shelf between
two ice rises. Similar inflow pathways may also exist beneath the ice front
sections of Nivlisen, explaining the variations of basal melt rates along
profile A (Fig. 2a). At Fimbulisen, higher basal melt rates (3 m yr-1)
were also observed and modelled close to the ice front at shallow depths
(<200 m; Hattermann et al., 2014; Langley et al., 2014b), which is
consistent with our results.
In the low-frequency radar profiles, we observed several undulating ice base
features (profiles A and B; Fig. 3), where the englacial layers warp
downwards, which is likely an indication of basal channels or crevasses. The
southernmost measurement in profile B is located at one of these
down-warping features, where surface elevation is slightly lowered locally
(-0.5 m). Higher basal melt rates were not observed here compared with the
surrounding sites, although higher melt rates typically occur on the flanks
of basal channels, rather than at their apex (Berger et al., 2017). The
channel may have formed at an upstream ice rumple and been passively
advected downstream (Fig. 2a). Basal channels are important features
influencing the ice shelf stability, since they affect ice shelf cavity
circulation and play a role in the exchange of heat and mass between the
ocean and ice shelf (Gladish et al., 2012; McGrath et al., 2012; Millgate et
al., 2013; Stanton et al., 2013). Basal channels are not restricted to
rapidly melting ice shelves and have been observed elsewhere in Dronning
Maud Land, at Fimbulisen (Langley et al., 2014a) and Roi Baudouin Ice Shelf
(Fig. 1a; Berger et al., 2017). Detailed studies of these features together
with basal melting are needed to understand their initiation, evolution, and
role in the overall mass balance of ice shelves (Alley et al., 2016).
Temporal variations in melting
Basal melt rates at Nivlisen varied on a broad range of timescales (Figs. 4
and 5). At the seaward site, we observed a seasonal signal, where the
monthly averaged basal melt rates were 2 to 3 times higher in
summer than in winter (Figs. 4a and S3). At the landward site,
we observed no seasonal pattern; however, some variability on monthly timescales was present (Figs. 5a and S3). We performed a continuous
wavelet transform on the time series data from the two overwintering sites,
based on the method and software package provided by Grinsted et al. (2004).
The wavelet transform is used to study localized intermittent periodicities,
in contrast to more traditional mathematical methods, such as a Fourier
analysis, which assumes that the underlying process is stationary in time.
We used a Morlet wavelet with ω0=6, which provides a good balance
between time and frequency localization. The wavelet transform shows the
normalized thinning rates at different scales to identify dominant periods
of variability in time (Figs. 4b and 5b). The statistical significance was
assessed relative to the null hypothesis, modelled by a 1st-order
autoregressive process. The wavelet transform has edge artefacts since it is
not completely localized in time, as indicated by the cone of influence,
masking out low-frequency signals at the beginning and end of the time
series. The thinning variability at diurnal timescales, and to some extent
semidiurnal timescales, varied at a period of approximately 2 weeks. This
reflects the fortnightly spring neap tidal cycle at which the strength of
the tidal currents varies because of the interference of different
constituents, usually the semidiurnal lunar tide (M2) and the semidiurnal solar tide (S2) in this area (plotted as white
dashed lines in Figs. 4b and 5b). Stronger tidal currents increase the heat
exchange at the ice–ocean interface and may hence cause more rapid melt. At
periods shorter than 36 h, however, we cannot differentiate the strain
signal from the melt signal. We also see some evidence of a slower
variability in the data centred on 2–4 d (Figs. 4d and 5d), which may be
a result of mesoscale activity passing by the site (eddies or internal
waves), which then show up in the melt rate. This is to some extent
supported by Fourier analysis of the normalized 36 h filtered basal melt
rates, which show peaks in power spectral density at 2–4 d, mostly
visible at the seaward site (Supplement Fig. S4).
Wavelet coherence between overlapping time periods at the
seaward and landward sites (4 January–27 November 2017) showing times where the
basal melt rates have common power. The phase relationship is shown as
arrows. At longer periods (8–30 d) in summer to autumn (January–April) the
signals are in phase, whereas in winter (April–June) the melt at the seaward
site leads the signal. In late winter (September) the phase shifts to the
landward site leading the signal. Within the cone of influence, shown as a
lighter shade, edge effects become important.
Basal melt rates compared with atmospheric forcing and
sea ice cover. (a) Values of 36 h low-pass filtered basal melt
rates at the seaward site (red) and landward site (blue). The shaded grey area
represents the time period in satellite data when there is open water in
front of the ice shelf (Supplement Fig. S6). ERA5 reanalysis surface data
of (b) wind speed and direction and (c) 2 m air
temperature, where the dashed black line is data from a nearby weather station
(Fig. 1b). Vertical dashed lines show where time lags were calculated
between basal melt and wind peaks.
At the landward site, we observed no increased melting in summer, but we
observed one melt peak in winter (12 June 2018; Fig. 5a). The melt event may
have been caused by pulses of modified warm deep water reaching the base of
the ice shelf as described by Hattermann et al. (2012), but it could also
relate to other mesoscale activities within the cavity. In any case, the
isolated event and the generally low basal melt rates suggest that warm deep
water had limited access to the base of Nivlisen during 2017 and 2018. This
observation is consistent with earlier studies, showing that ice shelf
cavities in this region are mainly filled with cold and fresh eastern shelf
water (Nicholls et al., 2006; Thompson et al., 2018). Many factors control
the extent to which warm deep water can access the ice shelf cavities in
Dronning Maud Land, such as the stability of the Antarctic slope front,
local circulation, and bathymetry, and this has to be studied in more
detail.
We studied the coherency between the two overwintering melt sites in a
wavelet coherence (Grinsted et al., 2004) for the overlapping time periods
in 2017 (Fig. 6). The wavelet coherence analysis finds significant coherence
even if the common power is low, and it shows significant confidence levels
against red-noise backgrounds. Locally phase-locked behaviour can also be
revealed; at weekly-to-monthly periods (7–30 d) in summer to autumn
(January–April 2017) the basal melt rates were in phase, whereas in winter
(April–June) the melting at the seaward site led the increased signal,
preceding the melt at the landward site. In late winter (September), the phase
shifted to the landward site leading the melt. At Fimbulisen, the inflow of
summer-warmed Antarctic surface water was observed at moorings close to the
ice shelf front with a clear seasonal signal in water temperatures and
salinity (Hattermann et al., 2012). Hattermann et al. (2014) suggested that
Antarctic surface water can reside for several months below the ice shelf
cavity, after initially being subducted beneath the ice front, potentially
affecting basal melting deep inside the cavity. The observed melt rate
pattern beneath Nivlisen may be an indication of similar movement of water
masses below the ice shelf, and further observations and modelling are needed
to study these processes, currently being hampered by the lack of knowledge
of bathymetry beneath the ice shelf.
We compared the basal melt rates with atmospheric reanalysis data from the ERA5 data set of
wind speed, wind direction, air temperature, and sea ice cover (Fig. 7)
produced by the European Centre for Medium-Range Weather Forecasts
(Copernicus Climate Change Service (C3S), 2017) at a grid point 10 km north
of the ice shelf front (Fig. 1b). ERA5 wind speeds at Nivlisen varied on
daily timescales ranging from 0 to 28 m s-1. Winds generally blew from
the east (Fig. 7b), corresponding to the pressure gradients imposed by the
cyclonic system that dominates the Weddell Sea. As wind forcing can play an
important role in the downwelling and transportation of summer-warmed Antarctic
surface water into the ice shelf cavity (Zhou et al., 2014), we calculated
the coherence between the normalized basal melt rates at the seaward site
and wind speeds during time periods when there was open water in front of
the ice shelf (grey area in Fig. 7a). The statistical significance level was
estimated using a Monte Carlo simulation with a Fourier transform method,
where a large set of surrogate data set pairs were generated using phase
randomization (Schreiber and Schmitz, 2000). We found a significant
coherence between basal melt rates and wind speeds (r=0.35, p<0.01; Fig. 8). We found no such coherence in winter. The variability in
winter may be due to the transport being mainly dominated by eddies, shed by
instabilities in the along-slope current. We also compared individual melt
peaks in summer with higher wind events (dashed vertical lines in Fig. 7).
The melt peaks have a time lag of ∼0 to 3 d after a wind event. Air
temperatures at 2 m varied mostly on seasonal timescales, with temperatures
between 0 and -10∘C in summer, when we observe the highest
basal melting, and down to -28∘C in winter (Fig. 7c). The
temperature variability in the reanalysis data on shorter timescales agreed
with our weather station on Leningradkollen (190 m a.s.l.);
however, the seasonal temperature signal had a lower amplitude than at the
weather station, which measured temperatures down to -38∘C.
When air temperatures were high and basal melt rates increased in early
summer at the seaward site (December 2016 and 2017), we observed open water close
to Nivlisen, which is the time when solar radiation may warm the surface
waters (Fig. 7). Sea ice is widespread in front of the ice shelf during
winter and then breaks up during summer typically starting from the west and
progressing to the more sheltered eastern side (Supplement Fig. S5). The
general pattern of summer retreat is interrupted by irregular periods of
some sea ice regrowth (e.g. early February 2017 and 2018; Fig. S5). Similar
seasonally higher basal melt rates (up to ∼5 m yr-1) were
observed at Ross Ice Shelf in West Antarctica, where solar-heated surface
water in a polynya near the ice front was linked to the higher melt rates;
however, they did not find any link to downwelling-favourable winds, but
rather a link was found for density gradients caused by seasonal brine release in the polynya
(Stewart et al., 2019).
Scatter plot with the normalized basal melt rates at the
seaward site and wind speeds for the time period when there was open water
in front of the ice shelf (grey area in Fig. 7a). Black points show the average
basal melt rate calculated for each wind speed bin in intervals of 0.25. The
red line shows the linear regression.
In summary, the basal melt rates varied on seasonal, monthly, and daily
timescales related to the tidal cycles and mesoscale activities in the
ice shelf cavity. We hypothesize that summer-warmed Antarctic surface water
was pushed by wind under the front of the ice shelf. Reduced sea ice cover
and higher wind speeds may increase melting from surface waters, while
weaker winds and/or changes in the surface buoyancy forcing may increase
exposure of the ice shelf cavities to warm deep water. Surface winds are
projected to intensify over the next century with increased greenhouse gas
emissions (Greene et al., 2017), and extreme changes in sea ice extent have
occurred in recent years (Shepherd et al., 2018). Warming of the surface
water is projected to increase ice shelf melting along Dronning Maud Land in
future climate scenarios (Kusahara and Hasumi, 2013), and recent studies
suggest that non-linear feedbacks may facilitate an irreversible transition
into a state of higher melting in the Weddell Sea (Hattermann, 2018; Hellmer
et al., 2017). Increases in basal melting will tend to thin the ice shelves
and reduce the buttressing on the inland ice sheet. It remains to be
understood to what extent increased summer warmth-driven melting,
intensified in the vicinity of pinning points, may affect the ice flow
dynamics and ice shelf stability.
Conclusions
We present a 2-year record of basal melting at Nivlisen in Dronning Maud
Land, East Antarctica, at a high spatial and temporal resolution using in situ
phase-sensitive radar measurements. Averaged annual basal melt rates are in
general moderate (0.8 m yr-1), but relatively high melt rates were
observed close to a grounded feature near the ice shelf front. Hourly
measurements also reveal a seasonal melt pattern close to the ice shelf front, where the highest basal melt rates occurred in summer (5.6 m yr-1). Comparing the seasonality in basal melting with forcing from
atmospheric reanalysis data, we found that the variability in the basal melt
is likely caused by summer-warmed surface water pushed by wind into the
ice shelf cavity. Farther into the ice shelf cavity, we observe a different
melt regime, with significantly lower basal melt rates and a clearer tidal
signal. We conclude that warm deep-ocean water has a limited effect on the
basal melting of Nivlisen, likely because the present configuration of the
Antarctic slope front, which separates the deeper water from the continent,
protects the ice shelf from those warmer water masses. Our study highlights
that, although many of the ice shelves in East Antarctica have generally low
basal melt rates, their seaward sections have temporally higher basal melt
rates due to the influence of summer-warmed surface waters. The frontal
areas are stabilized by pinning points, and these areas could potentially be
sensitive to future change if the basal rates would increase. We demonstrate
the use of and need for continuous in situ monitoring of Antarctic ice
shelves to resolve variability in basal melting that is not captured in
satellite data. Long-term, high-resolution time series data are crucial to
understanding the complex mechanisms involved in ice shelf–ocean
interactions.
Data availability
The compiled data sets of basal melt rates, strain rates, ice flow velocity, surface mass balance, and ice thickness from low-frequency radar profiling are available at the Norwegian Polar Institute (2019; https://data.npolar.no/; https://www.npolar.no/prosjekter/madice, last access: 1 September 2019).
The supplement related to this article is available online at: https://doi.org/10.5194/tc-13-2579-2019-supplement.
Author contributions
KL led the overall data analysis and interpretations and prepared the paper
with contributions from all co-authors. KL, GM, and BP collected the ApRES,
ice flow, and surface mass balance data. KWN was responsible for the ApRES
system setup. KM was responsible for the low-frequency radar system and
collected the data. TH contributed to the discussion section. MT and KM were
the project leaders.
Competing interests
Kenichi Matsuoka is a member of the editorial board of the journal.
Acknowledgements
This work was part of the MADICE (Mass balance, dynamics, and climate of the
central Dronning Maud Land coast, East Antarctica) project, funded by the Research Council of Norway and the Ministry of Earth Sciences,
India. We would like to thank
the NCPOR and NPI logistic heads and personnel who helped us in the field.
We also thank Chris Borstad for estimating flow lines to the ice rumple,
Harvey Goodwin for assessing field safety, Vikram Goel for helping collect data in the field, and Robert Graham for providing the ERA5 data. Figures 1
and 2 were prepared using Quantarctica (https://quantarctica.npolar.no/, last access: 1 September 2019). For the
REMA data set we acknowledge the following: DEMs were provided by the Byrd Polar
and Climate Research Center and the Polar Geospatial Center under NSF-OPP
award nos. 1543501, 1810976, 1542736, 1559691, 1043681, 1541332, 0753663,
1548562, and 1238993 and NASA award no. NNX10AN61G. Computer time was provided through a
Blue Waters Innovation Initiative. DEMs were produced using data from
DigitalGlobe, Inc. We thank the two anonymous reviewers and the editor Nanna
Bjørnholt Karlsson for their valuable suggestions and comments.
Financial support
This research has been supported by the Research Council of Norway (grant no. 248780) and the Ministry of Earth Sciences, India (grant no. MoES/Indo-Nor/PS-3/2015).
Review statement
This paper was edited by Nanna Bjørnholt Karlsson and reviewed by two anonymous referees.
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