1. Introduction
Fast-moving ice-streams and outlet glaciers form the major pathways for ice exiting the Antarctic continent; thus, their behavior exerts a dominant control on the mass balance of the Antarctic ice sheets (Reference Shabtaie and BentleyShabtaie and Bentley, 1987). However, far from being stable features, these fast-flowing regions of an ice sheet may exhibit fluctuations at a range of timescales. For example, the Siple Coast ice streams exhibit major century-scale shifts, driven by feedbacks in subglacial meltwater production and routing, producing periods of rapid motion (hundreds of m a–1) and stagnation (Reference VogelVogel and others, 2005; Reference Hulbe and FahnestockHulbe and Fahnestock, 2007). At the other end of the time spectrum, large (~100%) fluctuations of ice-stream velocity on a timescale of hours are observed near their grounding lines where elevated subglacial water pressures make the ice streams sensitive to small force-balance perturbations resulting from the rise and fall of the ocean tides (Reference Anandakrishnan, Voigt, Alley and KingAnandakrishnan and others, 2003; Reference GudmundssonGudmundsson, 2006; Reference Wiens, Anandakrishnan, Winberry and KingWiens and others, 2008; Reference Walter, Brodsky, Tulaczyk, Schwartz and PetterssonWalter and others, 2011; Reference Winberry, Anandakrishnan, Wiens, Alley and ChristiansonWinberry and others, 2011). A detailed understanding of the mechanisms regulating fluctuations in ice-stream behavior at all timescales, as well as the interactions across timescales, is needed to understand the evolution of ice sheets.
Whillans Ice Stream (WIS), a major drainage path of the West Antarctic ice sheet, exemplifies the temporal complexity of ice-stream behavior. Repeat measurements of velocity since the 1970s have documented a ~ 50% reduction in flow speed, indicating the ice stream may stagnate by the end of this century (Reference Stephenson and BindschadlerStephenson and Bindschadler, 1988; Bind-schadler and others, 2005; Reference JoughinJoughin and others, 2005). Complicating our understanding of this stagnation, however, is the relatively recent observation that the downstream portion of the ice stream accomplishes most of its motion during twice-daily 30 min bursts of motion, remaining largely stagnant the remainder of the day (Reference Bindschadler, King, Alley, Anandakrishnan and PadmanBindschadler and others, 2003).
In this contribution, we provide an updated overview of the dynamic behavior as well as ongoing changes occurring in the downstream portion of the ice stream, where WIS merges with Mercer Ice Stream to form a broad (~100 km) low-slope ice plain (Fig. 1). In Section 2, we document new details about the sticky spots that are thought to be responsible for stick–slip motion, and review the tidal pacing of the stick–slip cycle. In Section 3, we explore ongoing changes in ice-stream behavior, including long-term deceleration and surface-elevation changes and how these are related to stick–slip motion.
2. The Tidally Paced Stick–Slip Behavior Of Whillans Ice Stream
2.1. Sticky-spot locations
Similar to the motion on an earthquake fault, it has been proposed that the irregular stick–slip motion on the downstream portion of WIS is caused by small regions of high basal friction (sticky spots or asperities) at the ice/bed interface (Reference Winberry, Anandakrishnan, Wiens, Alley and ChristiansonWinberry and others, 2011). The strength of a sticky spot may balance the local driving stress and stress transmitted from surrounding regions, and under some conditions this can inhibit the stable sliding generally observed on ice streams (e.g. Reference ZoetZoet and others, 2013). In this model, between slip events, the relatively well-lubricated regions surrounding the sticky spot continue to move, producing elastic strain that results in an increasing applied shear stress on the sticky spot. When the applied shear stress exceeds the yield strength of the sticky spot, a slip event initiates. Rapid motion during the slip event dissipates the stored elastic potential energy, and, after motion stops, the cycle of stress accumulation starts anew. However, later in the paper, we show that viscous processes are likely important in understanding the WIS stick–slip motion.
In our earlier studies on WIS, isolating the location(s) of the sticky spot(s) was hampered by the relatively coarse spatial resolution of our GPS observations ~(50 km) collected during 2003/04 (four sites, ~130 days) and 2004/05 (20 sites, ~40 days). To overcome this limitation, we deployed a relatively dense (~10 km spacing) network of GPS near the center of the ice stream during the 2010/11 (25 sites, ~60 days) and 2011/12 (14 sites, ~21 days) austral summers (Fig. 1). The GPS datasets were processed using Precise Point Positioning methods (Reference Zumberge, Heflin, Jefferson, Watkins and WebbZumberge and others, 1997). Figure 2 shows the displacement time series at three stick–slip locations occupied in both 2004 and 2011. We found these sites to be suitably representative, with respect to both space and time.
A location of higher basal friction associated with a sticky spot has less inter-event motion than surrounding areas. For example, stations W3C and W2B have comparable mean velocities, but W3C moves more than W2B between slip events; we infer from this lower percentage of stick–slip motion at W3C that its bed is better lubricated. To examine the spatial pattern of slipperiness, we separate each displacement record into its inter-event and slip-event components and use these to determine the percentage of total motion that occurs during slip events at each location (Fig. 2). To provide the most spatially comprehensive view, we also include observations from 2004 that were not reoccupied in 2010/11. While some changes in flow occurred between the two time periods, as discussed below, this does not alter the first-order patterns of percent stick–slip (Fig. 3a).
The entire lower portion of the ice stream is characterized by relatively high values of percent stick–slip motion. However, the data show two broad maxima in stick–slip motion (displacement during slip events as a fraction of total motion), with values as high as 90%, which we call the central sticky spot (CSS) and the northern sticky spot (NSS). The CSS is shifted slightly from the location presented in previous work (Reference Wiens, Anandakrishnan, Winberry and KingWiens and others, 2008; Reference Winberry, Anandakrishnan, Wiens, Alley and ChristiansonWinberry and others, 2011), but within the uncertainty given the coarse nature of the previous surveys. The CSS fails during the first part of slip events and is the location of maximum total slip during slip events. The NSS fails during the second half of slip events, after significant motion over the CSS has occurred (Reference Winberry, Anandakrishnan, Wiens, Alley and ChristiansonWinberry and others, 2011).
Large sticky spots like those imaged in Figure 3a may result from several different mechanisms (Reference AlleyAlley, 1993). WIS is likely underlain by an extensive layer of till (unconsolidated sediment) (Reference Blankenship, Bentley, Rooney and AlleyBlankenship and others, 1987; Reference Kamb, Alley and BindschadlerKamb, 2001). The sensitivity of till properties to water pressure allows for a sticky spot to be associated with a relatively water-starved region where the low effective normal pressures required to sustain stable sliding cannot be maintained. Thus, we calculate the hydrostatic hydraulic potential beneath WIS assuming near-zero effective pressure:
where ρ i and ρ w are the densities of ice and water respectively, g is acceleration due to gravity, while z s and z b are the ice-sheet surface and bed elevations respectively (Reference ShreveShreve, 1972) using data from the Bedmap2 project (Reference FretwellFretwell and others, 2013).
Both sticky spots are associated with broad ridges that will tend to divert upstream subglacial water around these locations and increase effective pressure, consistent with the idea that, in this setting, stable sliding is inhibited by relatively high effective normal pressures (Fig. 3b). Thus, the present geometry of the ice stream directs the influx of upstream water required to maintain fast-flowing conditions (Reference Parizek, Alley, Anandakrishnan and ConwayParizek and others, 2002) away from the sticky spots into neighboring subglacial lakes (Fig. 3b; Reference Fricker and ScambosFricker and Scambos, 2009).
The initiation of a WIS slip event and the subsequent rupture across the stick–slip region are complex (Reference Wiens, Anandakrishnan, Winberry and KingWiens and others, 2008; Reference Sergienko, Ayeal and BindschadlerSergienko and others, 2009; Reference Walter, Brodsky, Tulaczyk, Schwartz and PetterssonWalter and others, 2011; Reference Winberry, Anandakrishnan, Wiens, Alley and ChristiansonWinberry and others, 2011), and a detailed discussion of these is beyond the scope of this contribution. Events occur just after high tide and just before low tide (described further below). Far-field seismic observations (hundreds of km away from WIS) detect two packets of energy during high-tide events, and three packets during low-tide events. Analysis of the rupture propagation during slip events by Reference Pratt, Winberry, Wiens, Anandakrishnan and AlleyPratt and others (2014) has identified three additional asperities that generate these packets of far-field seismic energy (labeled in Fig. 3a). All are located along the grounding line, and, although not directly associated with regions of measured minimum inter-event slip, the large energy radiation during events shows that they are regions of high basal friction. During the initiation of low-tide events, failure of asperity 1 radiates the first packet of far-field seismic energy observed; however, during high-tide slip events, failure of asperity 1 is not abrupt enough to generate teleseismic waves. During both high-tide and low-tide slip events, rapid reaccelerations of the ice stream originate from the sites labeled 2 and 3 in Figure 3a, at the northern edge of the NSS, to produce the other packets of far-field seismic energy.
2.2. The tidally paced stick–slip cycle
WIS typically has had two slip events per day, one just after high tide and one just before low tide; for simplicity, we refer to these as ‘high-tide’ and ‘low-tide’ events (Fig. 4). The pattern is not completely regular and is changing, as discussed below. Reference Bindschadler, King, Alley, Anandakrishnan and PadmanBindschadler and others (2003) observed that the timing between slip events is variable due to the tidal pacing of inter-event stress accumulation rate (Fig. 4). Because both events typically occur on the falling tide and the tide is dominantly diurnal in this region, a high-tide event typically follows a relatively long inter-event period (14–19 hours), with a shorter inter-event period (<9 hours) for low-tide events. Low-tide events are occasionally skipped, but we have not observed a skipped high-tide event. Additionally, during the neap tide the tidal phasing becomes less pronounced and the timing between slip events approaches the regular 12 hours (Reference Winberry, Anandakrishnan, Alley, Bindschadler and KingWinberry and others, 2009).
The tidal pacing of slip-event initiation arises from the modulation of flow speed near the grounding line (Reference Anandakrishnan, Voigt, Alley and KingAnandakrishnan and others, 2003; Reference GudmundssonGudmundsson, 2006; Reference Winberry, Anandakrishnan, Wiens, Alley and ChristiansonWinberry and others, 2011). Figure 5 shows the displacement time series for locations that display the range of stick–slip behavior for three consecutive stick–slip cycles observed in 2011. Station W3C is characterized by steady motion during inter-event periods, characteristic of sites upstream and transverse of the CSS. In contrast, near the grounding line (W2A) the ice stream moves more quickly on a falling tide in response to the changing force budget associated with Ross Sea tides. Thus, in general, during the spring tides, a relatively short inter-event period is favored after a high-tide event, due to the relatively higher rates of strain accumulation. However, a low-tide slip event will occasionally fail to nucleate near the transition to the rising tides; the subsequent tidally controlled slowing of motion at the downstream end then delays the next slip event until just after the subsequent high tide.
A second dominant control on the stick–slip cycle has been hypothesized to be a time-dependent strengthening of the subglacial interface following a slip event (Reference Winberry, Anandakrishnan, Alley, Bindschadler and KingWinberry and others, 2009). Such ‘healing’ behavior, strengthening the interface over time, is observed in laboratory studies (Reference MaroneMarone, 1998; Reference ZoetZoet and others, 2013) and is inferred for repeating earthquakes beneath the head of David Glacier, Antarctica (Reference Zoet, Anandakrishnan, Alley, Nyblade and WiensZoet and others, 2012). Beneath WIS, a strengthening mechanism could be related to sediment properties, such as pore-pressure diffusion or regelation into the bed (Reference AlleyAlley, 1993; Reference IversonIverson, 2010) or perhaps to thermal processes (Reference ZoetZoet and others, 2013). A time-dependent yield stress has been proposed to explain the observations that slip events that initiate following longer inter-event periods result in higher displacements due to the larger stress drops (Fig. 6). Thus, it is likely that short inter-event durations are favored on falling tides by both rapid stress accumulation and by the time-dependent strength of the sticky spot that allows slip-event initiation at a lower yield stress.
3. Observed Changes in Deceleration, Stick–Slip and Surface Elevation
Inspection of displacement time series reveals several changes in the ice stream’s behavior between 2003/04 and 2010/11 (Fig. 2). The most prominent change is the continued deceleration of the ice stream. Closer scrutiny also reveals changes in the regularity of the stick–slip cycle of the ice stream, with an increasing tendency to skip low-tide slip events (Fig. 4). In this section, we discuss changes in ice-stream behavior and geometry observed with both in situ and satellite instruments.
3.1. Flow-speed changes
The long-term deceleration of WIS has been well documented in several previous studies (Reference Joughin, Tulaczyk, Bindschadler and PriceJoughin and others, 2002, Reference Joughin2005; Reference Stearns, Jezek and Van der VeenStearns and others, 2005; Reference Scheuchl, Mouginot and RignotScheuchl and others, 2012) and has been linked to reduction in basal meltwater production, increasing strength of the underlying till, which in turn reduces basal motion (e.g. Reference Bougamont, Tulaczyk and JoughinBougamont and others, 2003). Our goal is to provide an updated compilation, including both spaceborne and field observations collected during the past 15 years, to elucidate any temporal complexity in the deceleration trend in the downstream portion where stick–slip motion dominates, with our findings similar to those recently reported by Reference Beem, Tulaczyk, King, Bougamont, Fricker and ChristoffersenBeem and others (2014).
The Siple Coast Project (SCP) in the 1980s made repeat measurements of stake locations by Transit satellite receivers, with an uncertainty of ~ 25 m a–1 (Reference Whillans, Bolzan and ShabtaieWhillans and others, 1987; Reference Stephenson and BindschadlerStephenson and Bindschadler, 1988; Reference BindschadlerBindschadler, 1993). More-recent point measurements of velocity have relied on continuous GPS observations. Mean annual velocities of stick–slip locations can be obtained by fitting a linear trend to the time series; uncertainties vary (due to length of occupation) but are small (<5 m a–1) (Reference JoughinJoughin and others, 2005). Additionally, during 1997 and 2009, interferometric synthetic aperture radar (InSAR) observations of WIS provided spatially continuous observations of velocities not possible with stake occupation methods (Reference JoughinJoughin and others, 1999; Reference Rignot, Mouginot and ScheuchlRignot and others, 2011), with uncertainties of 20 m a–1.
Flow speed histories can be constructed at discrete locations on WIS by coupling the InSAR observations with SCP measurements and subsequent GPS stake observations that are in close proximity to each other. Repeat GPS observations were made at the same geographic location (i.e. not by reoccupation of a stake that was advected downstream between observation periods). Figure 7 shows one example from an upstream location (B190) in the main trunk of WIS, upstream of the stick–slip region, and one downstream on the ice plain, characterized by stick–slip behavior (W3B). We also plot the shorter time series for an additional downstream stick–slip location (W2B) that is more centrally located but not near a SCP site. Each of these time series shows the prominent deceleration, an average of ~ 4–6 m a–2, reported in previous work (Reference Joughin, Tulaczyk, Bindschadler and PriceJoughin and others, 2002; Reference Bindschadler, Vornberger and GrayBindschadler and others, 2005).
The notable feature of the recent study by Reference Beem, Tulaczyk, King, Bougamont, Fricker and ChristoffersenBeem and others (2014) and our compilation is the observation that the rate of deceleration on the ice plain was smaller between 1997 and 2004 than before and after. Stations in the downstream portion of WIS display modest rates of deceleration (0–1 m a–2) between 1997 and 2004, relative to the long-term rates (4–6 m a–2). Repeat GPS measurements at W3B in 2003 and 2004 show an intermediate deceleration of ~ 3 m a–2, followed by a return to relatively high deceleration rates (~ 9 m a–2 or greater) between 2004 and 2009. Repeat GPS measurements at W3B and W2B document a rate of ~ 11 m a–2 between 2010 and 2011. In contrast to these downstream locations, upstream site B190 exhibits a steadier deceleration; the 1997–2003 rate may have a slightly lower magnitude than the long-term trend, but within the uncertainties in the InSAR datasets.
3.2. Skipped slips and their influence on mean flow speed
As discussed in earlier work (Reference Winberry, Anandakrishnan, Wiens, Alley and ChristiansonWinberry and others, 2011) and below, inter-event strain is predominately accumulated between the smooth-flowing upstream portion of the ice stream and the sticky spot located in the center of the ice plain (CSS, Fig. 3). This leads to the expectation that long-term rates of deceleration in the stick–slip portion of WIS should mimic those observed upstream in the steady-flowing regions due to the reduction in the daily accumulation of strain. However, the deceleration observed near the CSS (W3B, 15%) was significantly higher than in non-stick–slip locations (B190, 5%) between 2003/04 and 2010/11.
A conspicuous change in WIS’s behavior that coincided with this relatively rapid deceleration was the increase in the frequency of skipped events (Fig. 4). This change in behavior is reflected in the substantial increase in long inter-event periods (>20 hours) in the 2010/11 dataset, occurring on ~ 40% of days vs ~ 1% in 2003/04 (Fig. 8). During our observations, we recorded skips for low-tide events only; no skipped high-tide events were observed. As noted in previous studies and reviewed earlier, slip events following longer inter-event duration move farther; however, more motion is lost when a low-tide event is skipped than the extra slip in the following event, so that skips are associated with reduced average velocity. For example, during a neap tide, motion over the center of the ice stream (station W2B) is typically accommodated by two slip events that each follow a ~ 12 hour inter-event period, each resulting in ~ 0.47 m of displacement (Fig. 6), for a total of ~ 0.94 m of stick–slip motion during 24 hours. However, a slip event following an entire of day of dormancy moves only ~ 0.68 m, a 28% reduction in total motion.
The reduction in motion on single slip-event days accounts for the higher rates of deceleration observed in the stick–slip portion of WIS between 2003/04 and 2010/11. A similar relationship between inter-event duration and slip event displacement during 2004 and 2010 (Fig. 6) reveals that on normal days, those with two slip events, total motion was similar during each campaign. A linear regression through the data suggests a small downward shift in the trend (~ 2 cm per slip event) between 2004 and 2010, that corresponds to ~ 2% reduction in mean flow speed; however, this effect is small compared to the influence of the relative abundance of skipped low-tide events (40% of days). The lower motion during single-slip-event days accounts for two-thirds of the 60 m a–1 mean flow speed reduction (from 405 m a–1 to 345 m a–1) observed at station W2B between 2004 and 2010 (Figs 2 and 7), accounting for the higher rate of deceleration than observed upstream (i.e. station B190). Thus, while the long-term trend of deceleration is probably related to the strengthening of the ice-stream bed, the more-rapid deceleration between 2004 and 2010 was promoted by the increasing frequency of skipped events. Likewise, the relative stability of flow speed between 1997 (and perhaps earlier) and 2004 was likely sustained by the stability of the twice-daily stick–slip regime.
3.3. Elevation changes from ICESat
Our findings of unsteady deceleration prompted us to revisit the evolution of WIS as recorded by the Ice, Cloud and land Elevation Satellite (ICESat) mission (Reference AbshireAbshire and others, 2005). The ICESat mission provides 18 snapshots (averaged over ~ 1 month periods) from early 2003 until late 2009, thus spanning the transition from low to high deceleration rates recorded in the velocity observations. Several previous studies have evaluated elevation changes on WIS in an attempt to better understand the current deceleration (Reference Bindschadler, Vornberger and GrayBindschadler and others, 2005; Reference CsathoCsatho and others, 2005; Reference Smith, Bentley and RaymondSmith and others, 2005; Reference Pritchard, Arthern, Vaughan and EdwardsPritchard and others, 2009). Additionally, ICESat’s frequent repeat observations allowed for the discovery of an interconnected system of active subglacial lakes on the downstream portion of the ice stream (Reference Fricker, Scambos, Bindschadler and PadmanFricker and others, 2007).
We estimate surface-elevation change by measuring the difference between crossovers from different ICESat operational periods. Higher spatial resolution can be obtained by exploiting ICESat’s high along-track sampling (65 m footprints every 172 m); however, this analysis is complicated by technical issues that resulted in repeat tracks being offset by up to hundreds of meters (Reference Pritchard, Arthern, Vaughan and EdwardsPritchard and others, 2009). Fortunately, the proximity of WIS to the orbital limit of ICESat results in a relatively abundant and spatially extensive dataset of crossovers (~ 4 points per 25 km2 during each operational period). This spatial density is sufficient for a regional assessment, so we employed this approach.
We use ICESat Release 33 and correct for Gaussian-centroid range errors introduced by transmit-pulse reference selection using data and software obtained from the US National Snow and Ice Data Center (Reference Borsa, Moholdt, Fricker and BruntBorsa and others, 2014). We did not use any data points located above previously identified subglacial lakes. Firn corrections were not applied to the observed elevations due to the relatively small errors (<0.2 m) expected to be introduced for this region (Reference Pritchard, Ligtenberg, Fricker, Vaughan, Van den Broeke and PadmanPritchard and others, 2012). Spurious data points were identified automatically as any point measurements differing by >10 m from the ICESat-derived digital elevation model (Reference Bamber, Dans and GriggsBamber and others, 2009). We assessed the accuracy of the crossover analysis by calculating the standard deviation of crossovers for single laser periods; the 30 cm value is similar to previously published values (Reference Smith, Bentley and RaymondSmith and others, 2005) and sufficiently small that the pattern of changes detected between periods is highly significant. We calculated all surface elevation changes relative to the second ICESat laser operation period (operational period L2A ~ October 2003), the earliest operational period that provides a relatively high degree of spatial coverage. Figure 9 shows the elevation changes for WIS between late 2003 (operational period L2A) and early 2009 (operational period L2E), interpolated onto a 2 km grid and smoothed at 20 km.
As expected, the data clearly show development of a prominent surface-elevation change feature on WIS, a broad regional bulge ~ 1.5 m high at the junction between the main tributary and the ice plain (Fig. 9; Reference Pritchard, Arthern, Vaughan and EdwardsPritchard and others, 2009; Reference Carter, Fricker and SiegfriedCarter and others, 2013). This feature has been documented in earlier studies and reflects the higher rates of deceleration downstream vs upstream. To investigate any relationship between the rate of bulge growth and the previously described time variations in deceleration rate, we extracted a time series of relative elevations for a region of 25 km radius centered on the fastest-growing part of the bulge (Fig. 9). This time series shows minimal change in the early ICESat period (2003–06), followed by thickening (~ 0.3 m a–1) during the later period (2006–10). While we lack detailed velocity measurements between 2004 and 2009, the inflection in the elevation-change time-series data occurred at about the same time that the rate of deceleration and the number of skipped events began to increase downstream. As discussed below, physical understanding shows that these events should be linked. In turn, this suggests that the increased rate of deceleration downstream began towards the end of 2005 (Fig. 7b).
3.4. Slip efficiency and viscoelasticity
To understand the observed changes in behavior of WIS, we follow previous studies and model the force budget leading to the initiation of a slip event. The stress evolution on WIS sticky spot can be calculated assuming a simplified geometry of the ice stream, in which stresses on the sticky spot arise from compression upstream and extension downstream (Fig. 10). Our previous work (Reference Bindschadler, King, Alley, Anandakrishnan and PadmanBindschadler and others, 2003; Reference Winberry, Anandakrishnan, Alley, Bindschadler and KingWinberry and others, 2009, Reference Winberry, Anandakrishnan, Wiens, Alley and Christianson2011) relied on a simple elastic model of stress evolution.
where τ sticky-spot is shear stress on the sticky spot CSS, E is the Young’s modulus of ice (8.3 × 109 Pa; Reference GoldGold, 1958), x up and x dn are inter-event motion at the upstream and downstream end of the stick–slip region since the previous slip event, H up (1000 m) and H dn (750 m) are the average ice thickness upstream and downstream of the sticky spot respectively, while L up (100 km) and L dn (60 km) are the length upstream and downstream of the sticky spot respectively and W is the average width of the ice stream (~ 100 km). Unlike earlier studies, in this work we have isolated the location of the main sticky spot and distribute the shear stress across the area of the CSS, A sticky-spot (~ 500 km2), instead of the ice stream’s entire stick–slip length, as it appears to provide most of the resistance between slip events (Fig. 3a).
Motivated by the observed changes in stick–slip cycle and thickening at the upstream end of the stick–slip region, we depart from earlier efforts and also consider a viscoelastic approach to estimating the evolving force budget prior to a slip event initiation. We may represent the viscoelastic rheology of the ice stream as a Maxwell material with the differential equation for longitudinal compressive stress σ and its time-derivative
The first term on the right-hand side represents the elastic component of longitudinal deformation, and the second term is the viscous component (Glen’s flow law), where A is the flow law parameter (2.1 × 10–25 s–1 Pa–3 for ice at –150C, appropriate for WIS) (Reference Joughin, Tulaczyk, Bindschadler and PriceJoughin and others, 2002; Reference Cuffey and PatersonCuffey and Paterson, 2010). For WIS, we can estimate strain rate from upstream and downstream sources using
where v is the velocity and L is the length either upstream or downstream of the sticky spot (Fig. 10). Assuming that the applied stress is zero following the termination of a slip event, basal shear stress τ on the sticky spot is then estimated by summing the calculated upstream and downstream components of the applied stress
To investigate the significance of a viscoelastic rheology for modeling the force budget during a WIS stick–slip cycle, we calculate the stress evolution during a 30 hour period following the termination of a slip event for both a viscoelastic and elastic model (Fig. 11). We impose an upstream velocity of 1 m d–1, representative of the flow upstream of the stick–slip region, and a downstream velocity of 0.15 m d–1, the upper limit for the tidally modulated downstream flow speed, to simplify the analysis. This analysis ignores the tidal pacing, but allows for an understanding of rheological controls on the ice stream’s behavior. The total stress budget is plotted, as well as the upstream and downstream components. Similar to our previous work (Reference Bindschadler, King, Alley, Anandakrishnan and PadmanBindschadler and others, 2003; Reference Winberry, Anandakrishnan, Alley, Bindschadler and KingWinberry and others, 2009, Reference Winberry, Anandakrishnan, Wiens, Alley and Christianson2011), the upstream component dominates the total stress budget, accounting for ~ 75% of the total stress accumulation. Values are ~ 5 times higher than reported in our previous studies, because we are balancing the entire force on the CSS instead of distributing the force across the entire ice-stream bed. During the early stages of an inter-event period, the elastic and viscoelastic models are similar, because initially the stress is low so that viscous deformation, with its cubic dependence on stress, remains very low. Divergence between the elastic and viscoelastic models becomes evident in the region upstream of the sticky spot ~ 15 hours after the termination of a slip event. In contrast, the lower strain rates and associated stresses found downstream of the sticky spot cause the stress regime to be dominated by elastic processes even at relatively long inter-event periods. Thus, while a simple elastic model accurately represents stress evolution of slip events initiating after inter-event periods of less than ~ 15 hours, for longer time intervals viscous deformation becomes significant upstream of the sticky spot, reducing the rate of stress accumulation.
Motion in a stick–slip system, such as WIS, is linearly related to the amount of elastic strain released during slip events. However, the viscous deformation that occurs following a skipped low-tide event results in a net reduction in the total elastic strain (and stress drop) available for release during a day experiencing a single slip event. We observe from Figure 6 that during a slip event nucleating after 24 hours the ice stream moves ~ 150% farther than an event nucleating after 12 hours, not ~ 200% as would be expected with a doubling of strain accumulation in the elastic model. However, the viscoelastic calculation shows only a ~ 150% increase in stress drop (19 vs 13 kPa), comparable to the displacement ratio observed between slip events occurring after 24 hours vs 12 hours (Fig. 6).
The exact amount of reduced stress drop resulting from the onset of viscous deformation will depend on the creep parameter A. We examine this sensitivity by repeating the viscoelastic calculations for a range of creep parameters (1.2–3.2 × 10–25 s–1 Pa–3) that encompass a plausible range of mean ice column temperatures (–20 to –10°C) for WIS (Fig. 11). As expected, for colder, stiffer ice the deviation from a purely elastic model is less pronounced; however, all values of A exhibit a reduction in stress levels beginning ~ 15 hours into a stick–slip cycle and a net reduction in applied shear stress for slip events nucleating following a 24 hour inter-event period.
The value of E is also at least somewhat uncertain, as is the magnitude of additional stress supported on the sticky spot from flowlines in the ice stream that do not pass through the sticky spot. Thus, the magnitude of the viscous relaxation during longer inter-event times cannot be calculated precisely from the motion at the boundaries and material properties. Nonetheless, we can say with confidence that viscous deformation is significant for the longer inter-event times, providing a first-order explanation for the low total motion observed during single slip-event days.
This explanation predicts that the increasing skips will have caused net thickening upstream of the sticky spot. (Total ice motion during our study period is small compared to the length of the stick–slip region, and the ice stream is laterally constrained by ice ridges, so longitudinal compressive strain must be balanced by vertical extension.) Thickening is indeed observed (Fig. 9). We will briefly explore whether the viscous deformation between slip events associated with long inter-event periods following skipped low-tide events provides a quantitatively viable mechanism to explain the observed thickening between 2005 and 2009, while recognizing that the ICESat observations exhibit spatial complexity that will not be represented by our simple approximation of the ice stream.
To estimate thickening, we partitioned the average vertical deformation between elastic (recoverable during slip events) and viscous (permanent) deformation at the upstream end of the ice stream as a function of time since the previous slip event (Fig. 12). This was done by subtracting the viscous deformation from the total vertical deformation resulting from compression using the results presented in the main panel of Figure 11. After 24 hours since the previous slip event, ~ 0.002 m (or 20%) of the vertical deformation is permanent. In the 2010/11 datasets, single slip events were observed on 40% of days (~ 150 slip events per year), leading to an annual thickening rate of ~ 0.3 m, comparable to that observed from ICESat. We could adjust the flow law parameter or other parameters to improve or degrade the fit; however, at the order-of-magnitude level or better, the broad bulge forming at the upstream end of the ice stream can be attributed to viscous deformation during long inter-event periods.
3.5. Mechanisms for the increasing number of skipped slip events
We now consider the origin of the increased frequency of skipped low-tide events in the 2010/11 observations. The reduced frequency of slip events indicates a delay in reaching the basal yield stress and could be indicative of an increase in the strength of the sticky spot, a reduction in the rate of stress accumulation, or a combination of the two. To decipher the relative role of these effects, we use the viscoelastic model to calculate shear stress evolution preceding all slip events during the 10 days in 2004 and 20 days in 2011 that downstream locations were operational. No grounding-line sites were installed during 2003 and 2010. Due to the limited station coverage, we estimate the upstream strain rate using a steady inter-event velocity of 1.11 m d–1 in 2004 and 1.03 m d–1 in 2011 based on the 1997 and 2009 InSAR datasets. This accounts for the continued deceleration of steady-flowing regions upstream of the stick–slip region. The tidally modulated downstream strain rate is estimated from station W2A.
We first examine whether increases in sticky-spot strength are a viable mechanism to explain the increasing number of skipped slip events by calculating basal shear stress on the sticky spot at slip initiation (Fig. 13). This analysis confirms and extends previous work (Reference Winberry, Anandakrishnan, Alley, Bindschadler and KingWinberry and others, 2009; Reference Walter, Brodsky, Tulaczyk, Schwartz and PetterssonWalter and others, 2011) showing higher yield stress with longer waiting time, reflecting the progressive strengthening (or healing) of the ice/bed interface following each slip event; long inter-event times arising from skipped events were observed in 2011 but not 2004 in this dataset, explaining all of the high-stress events shown. An increase in the mean bed strength would result in a reduced amount of slip for a given amount of accumulated shear stress. However, we observe a consistent yield-stress/time relationship associated with the onset of slip event initiation during both 2004 and 2011, suggesting that the bed beneath the sticky spot did not undergo significant strengthening between the two time periods (Fig. 13). This is consistent with the relatively constant time-slip magnitude (Fig. 6), although scatter in the data makes small changes difficult to detect. We thus do not consider changes in the strength of the sticky spot to be the primary candidate for driving the increased frequency of skipped low-tide events. While the upstream portion of the ice stream continues to slow due to an increase in basal drag (e.g. Reference Beem, Tulaczyk, King, Bougamont, Fricker and ChristoffersenBeem and others, 2014), the changes in mean strength of the stick–slip dominated region appear to be small (<2– 3 kPa between 2004 and 2011).
The other likely potential driver of the skipped slip events is a change in the inter-event stressing rate. In the absence of a modulated stressing rate (e.g. by the tides), slip events will typically be evenly spaced in time. Thus, the effect of a reduced stressing rate will be to increase the time separation between consecutive slip events. On WIS, deceleration of the upstream reach reduced the stressing rate on the sticky spot (CSS) by ~ 0.06 kPa h–1 (0.94 vs 0.88 kPa h–1) between 2004 and 2011. As a result of this lower stressing rate, 12 hours into an inter-event period during 2011 the accumulated shear stress was ~ 0.72 kPa lower than in 2004. From Figure 14, we observe that the modeled bed strength increases by ~ 0.7 kPa h–1 during both 2004 and 2011. Thus, the reduced 2011 stressing rate will on average delay onset of a slip event by ~ 1 hour relative to 2004.
To assess the role of reduced stressing rates in the dynamics of the tidally modulated WIS, we have classified slip events into four major categories based on the inter-event duration preceding the slip event: low tide (<9 hours), normal high tide (14–19 hours), neap tide (10–14 hours) and those following skipped low tides (>19 hours) (Fig. 14). We then measured the time lag between slip-event initiation and either the low tide (low-tide events) or high tide (all other events) of the Ross Sea. While scatter is present in the data, clear shifts in timing are observed that are consistent with the reduced inter-event stressing rate. On average, low-tide events are delayed by 1–2 hours, initiating closer to low tide in 2010/11 relative to 2003/04. Likewise, high-tide events are shifted away from high tide by a similar amount. In both sets of observations neap-tide events display no strong phasing with the tides, while events following skipped low-tide events tend to nucleate following the subsequent high tide. A more subtle change, which is likely the result of a reduced stressing rate, is the shift in the amount of time required to initiate a slip event from ~ 6 to ~ 8 hours between 2003/04 and 2010/11 (Fig. 8).
This increase in inter-event duration coupled with sensitivity of slip initiation to the tidal modulation of downstream inter-event motion (Fig. 5) generates more favorable conditions for the skipping of low-tide events in 2010/11. First, the reduced loading has the effect of delaying high-tide events by ~ 1 hour (Fig. 14). Since high-tide events typically nucleate on the falling tide, the result is to lower the time over which rapid downstream motion may increase stress on the sticky spot to initiate the subsequent low-tide event. Second, as with the high-tide event, lower upstream loading delays initiation by an additional ~ 1 hour. Thus, the combined effect of the delayed high-tide event coupled with lower inter-event stressing rate is to shift low-tide events from typically nucleating ~ 2 hours before the low tide in 2003/04 to near low tide in 2010/11 (Fig. 14), increasing the probability that a slip event will not be initiated prior to the rising tide. Subsequent to the low tide, continued strengthening of the sticky spot may outpace the decreased stressing rates associated with a rising tide, increasing the likelihood of a skipped low-tide event.
4. Summary
We have investigated the complex behavior of the decelerating WIS. We have isolated the location of the large sticky spots that hinder stable flow in the stick–slip portion of the ice stream. The sticky spots are situated on broad (~ 40 km radius) highs in the subglacial hydropotential that preferentially divert water into surrounding large subglacial lakes. The relatively low surface slopes presently found on the ice plain favor the formation of such large subglacial lakes that will promote localized storage of subglacial water and the formation of large sticky spots. Additionally, recent work shows that the large bulge forming at the upstream end of the stick–slip region influences the drainage paths between the subglacial lakes beneath WIS (Reference Carter, Fricker and SiegfriedCarter and others, 2013). These results provide further evidence that the coupled evolution of large sticky spots and subglacial lakes may play a crucial role in understanding the dynamic behavior of the ice stream (Reference Fricker, Scambos, Carter, Davis, Haran and JoughinFricker and others, 2010; Reference Sergienko and HulbeSergienko and Hulbe, 2011).
The onset of stick–slip motion due to the development of large sticky spots (>20 km diameter) has a fundamental influence on ice-stream behavior during stagnation. In traditional models of oscillatory ice-stream behavior (Reference PaynePayne, 1998; Reference Bougamont, Tulaczyk and JoughinBougamont and others, 2003), evolution of local thermal conditions and associated changes in basal drag regulate the evolution of surface flow speed. In contrast to this expectation, the basal shear strength of the main sticky spot on WIS appears to be undergoing minimal or no change, suggesting that the subglacial till beneath this region is sufficiently depleted of water that no significant evolution of porosity and strength is occurring. However, we have shown that the stick–slip-style behavior that dominates the downstream portion of the ice stream introduces unsteadiness in the deceleration, not due to local conditions, but through interactions with the steady-flowing but decelerating upstream portions of the ice stream. It is possible that in the future, low-tide slip events will become completely absent. In such a scenario, it is likely that deceleration in the downstream portion of the ice stream will decrease to a rate comparable to that observed upstream of the stick–slip region.
It is becoming increasingly clear that processes characterized by a range of timescales influence the evolution of ice sheets. Our work provides further evidence of how short-timescale (days to months) processes can influence longer-term evolution (decades to centuries) of an ice sheet. While the large-scale stick–slip style of motion is unique among active ice streams, the low driving stress conditions that make stick–slip possible were likely common in past configurations of the West Antarctic ice sheet when low-slope ice streams extended outward to the continental shelf (Reference Denton and HughesDenton and Hughes, 2002). Additionally, unsteadiness in behavior at short timescales in response to small perturbations, such as documented here, provides unique windows into the fundamental physics of glaciers and ice sheets.
Acknowledgements
We thank Alex Brisbourne, Peter Burkett, Angela Hoffer, Randy Justin, Tarun Luthra and Stephanie Kay for help with data collection in 2010 and 2011, and the entire TIDES team for data collection efforts in 2003 and 2004. GPS data were processed using Natural Resources Canada’s PPP-direct service. Instrumentation and support was provided by the University Navstar Consortium (UNAVCO) instrument center. Logistical support was provided by Raytheon Polar Services, the New York Air National Guard and Kenn Borek Air. Ross Sea tides were computed using software provided by Laurence Padman. We thank investigators as well as the US National Snow and Ice Data Center for making ICESat, MODIS, InSAR and Siple Coast Project datasets publicly available. Two anonymous reviews improved the quality of the presentation. This work was supported by the US National Science Foundation Office of Polar Programs grant 0944794.