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A new cycle of jökulhlaups at Russell Glacier, Kangerlussuaq, West Greenland

Published online by Cambridge University Press:  08 September 2017

Andrew J. Russell
Affiliation:
School of Geography, Politics and Sociology, Newcastle University, Newcastle-upon-Tyne NE1 7RU, UK E-mail: [email protected]
Jonathan L. Carrivick
Affiliation:
School of Geography, University of Leeds, Leeds LS2 9JT, UK
Thomas Ingeman-Nielsen
Affiliation:
Arctic Technology Centre, Technical University of Denmark, Kemitorvet B-204, DK-2800 Lyngby, Denmark
Jacob C. Yde
Affiliation:
Center for Geomicrobiology, University of Aarhus, Ny Munkegade, B-1540, DK-8000 Aarhus, Denmark Bjerknes Centre for Climate Research, University of Bergen, Allegaten 70, NO-5007 Bergen, Norway
Meredith Williams
Affiliation:
School of Civil Engineering and Geosciences, Newcastle University, Newcastle upon Tyne NE1 7RU, UK
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Abstract

Jökulhlaups in 2007 and 2008 from an ice-dammed lake at the northern margin of Russell Glacier, West Greenland, marked the onset of a renewed jökulhlaup cycle after 20 years of stability. We present a record of successive ice-dammed lake drainage events and associated ice-margin dynamics spanning ∼25 years. Robust calculations of lake volumes and peak discharges are made, based on intensive field surveys and utilizing high-spatial-resolution orthophotographs of the lake basin and ice margin. These data enable identification of controls on the behaviour of the ice-dammed lake and provide the first field-based examination of controls on jökulhlaup magnitude and frequency for this system. We find that Russell Glacier jökulhlaups have a much higher peak discharge than predicted by the Clague–Mathews relationship, which we attribute to an unusually short englacial/subglacial routeway and the presence of a thin ice dam that permits incomplete sealing of jökulhlaup conduits between lake drainage events. Additionally, we demonstrate that the passage of jökulhlaups through an interlinked system of proglacial bedrock basins produces significant attenuation of peak discharge downstream. We highlight that improved understanding of jökulhlaup dynamics requires accurate information about ice-dammed lake volume and ice-proximal jökulhlaup discharge.

Type
Research Article
Copyright
Copyright © International Glaciological Society 2011

Introduction and Aims

Glacier-dammed lakes exist in many parts of the world and often pose an extreme hazard when they drain rapidly, generating jökulhlaups (glacial outburst floods). Glacier margin recession from tributary valleys has resulted in the formation of new ice-dammed lakes and the destabilization of existing ice-dammed lakes through lowering and weakening of ice dams. Increases in meltwater production have resulted in the formation and destabilization of many ice-dammed lakes (e.g. Reference Wiles, Barclay, Calkin and LowellWiles and others, 2008). While controls on ice-dammed lakes have been described from intensive field campaigns (e.g. Reference WalderWalder and others, 2006; Reference Huss, Bauder, Werder, Funk and HockHuss and others, 2007), detailed investigations of cycles of repeated draining of a single ice-dammed lake are quite rare (e.g. Reference Mathews and ClagueMathews and Clague, 1993; Reference Roberts, Pálsson, Guðmundsson, Björnsson and TweedRoberts and others, 2005; Reference Ng, Liu, Mavlyudov and WangNg and others, 2007; Reference Ng and LiuNg and Liu, 2009). In Greenland, a number of ice-dammed lakes are known to drain periodically (e.g. Reference HelkHelk, 1966; Reference HigginsHiggins, 1970; Reference DawsonDawson, 1983; Reference ClementClement, 1984; Reference Mayer and SchulerMayer and Schuler, 2005), but little is known about the controls on these long-term drainage cycles.

The ice-dammed lake on the northern flank of Russell Glacier (Fig. 1) drained in July 1987 (Reference Russell and de JongRussell and de Jong, 1988; Reference RussellRussell, 1989, Reference Russell1993c), marking the termination of a cycle of at least eight jökulhlaups, identified from sediment;ary evidence within the proglacial jökulhlaup channel (Reference RussellRussell, 2009). The first evidence of jökulhlaups from this ice-dammed lake is provided by major proglacial channel morphological change, identified from aerial photographs taken in 1944 and 1953 (Reference RussellRussell, 1993a). A jökulhlaup on 31 August 2007 marked renewed ice-dammed lake drainage after 20 years of stability (Reference Mernild, Hasholt, Tidwell and KaneMernild and others, 2008; Reference Česnulevičius, Šeiriené, Kazakauskas, Baltrūnas, Šinkūnas and KarmazaČesnulevičius and others, 2009; Reference Mernild and HasholtMernild and Hasholt, 2009). A subsequent jökulhlaup on 31 August 2008 demonstrated that the 2007 jökulhlaup indeed marked the onset of a new cycle.

Fig. 1. Location of field area within Greenland and in relation to the Kangerlussuaq and Kellyville GPS site (KELY). The ice-dammed lake, outlet lake 1 (OL1) and outlet lake 2 (OL2) are shown in relation to the northern margin of Russell Glacier. The ice-dammed lake drains through an englacial/subglacial tunnel, indicated by a dashed arrow, for a distance of ∼1 km, routing jökulhlaups into OL1. Proglacial jökulhlaup peak discharge reconstructions were undertaken at the spillway between OL1 and OL2 and at the 1987 gauged reach (labelled ‘Gauge’).

The onset of a new jökulhlaup cycle at Russell Glacier is important because ice-dammed lake level, extent and stability are known to fluctuate in response to climate-driven fluctuations of ice thickness and glacier margin position (Reference ThórarinssonThórarinsson, 1939; Reference Evans and ClagueEvans and Clague, 1994; Reference AndersonAnderson and others, 2003). However, most knowledge of ice-dammed lake drainage processes is derived from the analysis of lakes impounded by glaciers that have undergone progressive retreat since the Little Ice Age (e.g. Reference Clague and MathewsClague and Mathews, 1973; Reference Desloges, Jones and RickerDesloges and others, 1989; Reference Walder and CostaWalder and Costa, 1996; Reference Ng and BjörnssonNg and Björnsson, 2003; Reference Ng, Liu, Mavlyudov and WangNg and others, 2007). Reference Evans and ClagueEvans and Clague (1994) presented a model of the ‘jökulhlaup cycle’ where glacier recession, accompanied by reduction in ice-dammed lake volume, generates a cycle of jökulhlaups of progressively decreasing magnitude.

We present an examination of the characteristics of, and controls on, the behaviour of an unnamed ice-dammed lake at Russell Glacier, near Kangerlussuaq, West Greenland. To do this we (1) reconstruct the volume and peak discharge of the 2007 and 2008 jökulhlaups from Russell Glacier, (2) recalculate the volume and peak discharge of jökulhlaups in 1984 and 1987 from the same ice-dammed lake utilizing new data and (3) evaluate controls on the jökulhlaup cyclicity at Russell Glacier.

Study Area and Methods

Russell Glacier is an outlet glacier on the western margin of the Greenland ice sheet, located 35 km east of Kangerlussuaq (Søndre Strømfjord) (Fig. 1). The Russell Glacier meltwater catchment has an area of ∼90 km2 (Reference Van de Wal and RussellVan de Wal and Russell, 1994), with summer ablation controlled discharges of up to 70 m3 s−1 (Reference RussellRussell, 1989; Reference Van de Wal and RussellVan de Wal and Russell, 1994; Reference Russell, Tatenhove and van de WalRussell and others, 1995). Within the Kangerlussuaq meltwater catchment, of which the Russell Glacier meltwater catchment is part, jökulhlaups have originated from the draining of ice-marginal lakes (Reference Russell, Aitken and de JongRussell and others, 1990), supraglacial lakes (Reference RussellRussell, 1990, Reference Russell1993c) and ice-debris-dammed lakes (Reference Russell, Tatenhove and van de WalRussell and others, 1995). Repeated jökulhlaups from the largest ice-marginal ice-dammed lake at the northern margin of Russell Glacier are relatively well documented (e.g. Reference Sugden, Clapperton and KnightSugden and others, 1985; Reference GordonGordon, 1986; Reference Russell and de JongRussell and de Jong, 1988; Reference Scholz, Schreiner and FunkScholz and others, 1988; Reference RussellRussell, 1989, Reference Russell1993b, Reference Russell2007, Reference Russell2009; Russell and Marren, 1999). The 1984, 1987, 2007 and 2008 jökulhlaups all routed through a 1 km long subglacial/englacial tunnel at the southwestern corner of the ice-dammed lake (Figs 2 and 3a and b) before flowing out across a coarse-grained delta into outlet lake 1 (OL1) (Figs 1 and 2) (Reference RussellRussell, 1989, Reference Russell2007; Russell and Marren, 1999). Jökulhlaups drain from OL1 northwards into outlet lake 2 (OL2) via a bedrock spillway whose cross-sectional shape controls the level of the upper lake (Figs 1 and 2) (Reference RussellRussell, 2007). On exiting OL2, jökulhlaups flow through a series of bedrock-confined channels and outwash plains before flowing west along the glacier snout (Fig. 1).

Fig. 2. Ice-dammed lake at the northern margin of Russell Glacier, on 21 July 1987 and 24 May 2008. Both photographs were taken immediately after a jökulhlaup, permitting comparison between the lake level drops. Arrows indicate common points, and are used for examining ice-margin position and thickness.

Fig. 3. Recent visual history of ice-dammed lake dynamics. (a) 1985 aerial photograph by Danish National Survey and Cadastre shows low lake level, smaller lake surface area and thinner ice. (b) 2006 aerial photograph by ARTEK shows maximum lake level, larger lake volume and thicker ice. Maximum lake level is controlled by a proglacial bedrock spillway which drains into OL1. (c) Tracks of a kinematic dGPS survey undertaken in February 2008 to interpolate lake basin bathymetry. (d) Lake bathymetric model with contours at 5 m intervals. Maximum lake level illustrated is 453.7 m. Lake levels were measured in May 2008.

Fieldwork conducted in October 2007 and February 2008 comprised bathymetric surveying of the ice-dammed lake (Fig 3c and d) using a Trimble 4600 LS single-frequency, differential global positioning system (dGPS) with a stated accuracy ±20 cm in real-time kinematic (RTK) mode. Fieldwork conducted in May 2008 included precision surveying of the ice-dammed lake level, proglacial lake water surface and wash limit levels, and proglacial jökulhlaup channel cross-sectional areas. This May 2008 fieldwork was carefully timed to obtain data on the 2007 jökulhlaup lake level and 2007 jökulhlaup wash limits while the evidence was still intact. Maximum jökulhlaup water levels were determined from wash limits that comprised erosional trimlines, trash lines of shrub twigs and leaves, silt cover on vegetation and the upper extent of ice block melt-out deposits (e.g. Reference Carrivick and RushmerCarrivick and Rushmer, 2009). All positions and heights surveyed in May 2008 were obtained using a Leica GPS500 dGPS used in RTK mode with occupation of temporary base stations. Base stations were precisely located by post-processing relative to continuous dGPS data for Kellyville ‘KELY’ GPS station, 45 km away. Our surveyed points (Fig. 3c) have a mean three-dimensional error of <10 cm (commonly <1 cm) which makes our measurements comparable in accuracy to those of previous surveys (e.g. Reference RussellRussell, 1989). The relative accuracy of the Trimble and Leica dGPS locations was assessed from points common to both datasets; these points are within 0.5 m of each other, and the mean elevation difference is 0.211 m.

Peak discharge was reconstructed using three techniques: (1) Walder and Costa’s (1996) empirical relationship utilizing ice-dammed lake volume, (2) the slope/area technique at three stable proglacial channel cross sections and (3) a spillway equation used to reconstruct flow exiting OL1 over a bedrock lip.

Reference Walder and CostaWalder and Costa (1996) present an empirical power-law relationship between maximum jökulhlaup discharge, Qmax, and volume of water drained, V, for a dataset of 26 ice-dammed lakes which drain subglacially. The Walder and Costa relationship, which builds on the Clague–Mathews relationship, was used to estimate jökulhlaup peak discharge from ice-dammed lake volume (Reference Clague and MathewsClague and Mathews, 1973; Reference Ng and BjörnssonNg and Björnsson, 2003):

(1)

The slope/area technique was used to reconstruct peak flood discharge within proglacial jökulhlaup channels. The bedrock spillway between OL1 and OL2 provides a stable channel cross-sectional geometry, confirmed by pre- and post-2007 channel cross-sectional surveys and observations. Reconstructions downstream of OL2 were made at a stable reach used to gauge the 1987 jökulhlaup (Reference RussellRussell, 1989, Reference Russell1993b, Reference Russell2009; Russell and Marren, 1999). The peak discharge of the 1987 jökulhlaup was reconstructed for comparison with discharge measured directly during that event (Reference RussellRussell, 1989), providing validation of the hydraulic techniques used.

Mean flow velocities for each channel cross section were calculated using three variants of the standard Manning resistance equation, as well as an adaptation of the Keulegan equation (Reference Thompson and CampbellThompson and Campbell, 1979; Reference Russell, Marren, Jones, Tucker and HartRussell and others, 1999, Reference Russell, Gregory, Large, Fleisher and Harris2007; Reference Carrivick, Russell, Tweed and TwiggCarrivick and others, 2004; Reference CarrivickCarrivick, 2007a). The Manning and Keulegan resistance equations require the input data: (1) energy gradient or water surface slope, (2) channel hydraulic radius and (3) grain roughness (Reference ChowChow, 1959; Reference HendersonHenderson, 1966; Maizels, 1983). Four methods were used to characterize grain and form roughness in order to identify potential problems of incorporating the channel resistance. Water surface slope was derived from observed water surfaces and well-defined wash limits for the 1987 and 2007 jökulhlaups, respectively. Channel hydraulic radius was calculated from cross-sectional areas and wetted perimeters derived from surveyed channel cross sections. Channel roughness was characterized by the Darcy–Weisbach friction factor, f, and Manning’s n. The modified Keulegan equation proposed by Reference Thompson and CampbellThompson and Campbell (1979), being the least empirical and least site-specific, was used to calculate f in the Darcy–Weisbach equation (Reference Church, Wolcott and MaizelsChurch and others, 1990). The Darcy–Weisbach equation was used to obtain mean velocity, v:

(2)

where g is the acceleration due to gravity (9.81 m s−2), d is the flow depth (m), s is the slope and f is calculated using Thompson and Campbell’s (1979) equation:

(3)

where R is the hydraulic radius (m) and k s is the size of the roughness elements, equal to 4.5 times the clast size, Di . In this case, we calculated k s as the proportion of the flow depth, d, occupied by flow resistance elements, ΔA:

(4)

The proportion of the flow depth occupied by flow resistance elements, ΔA, consisting of boulders, was estimated visually and expressed as a percentage. A single f value was calculated for each cross section. Calculated f values were converted to Manning’s n using an equation presented by Reference RichardsRichards (1982):

(5)

Manning’s n roughness values were firstly calculated from grain-size characteristics using the Manning–Limerinos and Manning–Strickler equations:

(6)

(7)

where D 84 and D 90 are the 84th and 90th percentile grain-size values, respectively. D 84 and D 90 percentiles were derived for each cross section from visual estimates of surface grain sizes (Maizels, 1983; Reference Ryder and ChurchRyder and Church, 1986; Reference RussellRussell, 1994). Secondly, and for comparison with n values from observations of grain roughness, n values were also calculated solely from water surface slope and the hydraulic radius, i.e. from form roughness, using Jarrett’s (1984) equation:

(8)

where S is the downstream water surface gradient.

Overall, mean flow velocities were derived for each proglacial channel cross section using each of the four variants of the slope/area technique presented above. Peak flood discharges were derived by multiplying mean flow velocities by channel cross-sectional areas.

Instantaneous outflow discharge, Q w (m3 s −1), from the maximum level of OL1 was calculated using the spillway equation (Reference Featherstone and NalluriFeatherstone and Nalluri, 1982):

(9)

where A is the cross-sectional area of the spillway (m2) and b is water surface width (m).

Results

Ice-dammed lake volume: 1984–2008

Draining of the ice-dammed lake on the northern margin of Russell Glacier occurred on 31 August 2007 and lasted for ∼17 hours (Reference Mernild, Hasholt, Tidwell and KaneMernild and others, 2008; Reference Česnulevičius, Šeiriené, Kazakauskas, Baltrūnas, Šinkūnas and KarmazaČesnulevičius and others, 2009; Reference Mernild and HasholtMernild and Hasholt, 2009) (Fig. 2). Our direct measurements of the ice-dammed lake basin in October 2007 show that the lake did not drain completely, but that the water level lowered by 49.2 ± 0.2 m (Table 1). This lowering differs significantly from Mernild and others’ (2008) estimate of ∼25 m and also from Česnulevičius and others’ (2009) value of 55 m. Our measured lake volume drained during the 2007 jökulhlaup was (39.± 10.8) × 106 m3 (Table 1). This volume is far greater than published values of 11.3 × 106 m3 (Reference Mernild, Hasholt, Tidwell and KaneMernild and others, 2008; Reference Mernild and HasholtMernild and Hasholt, 2009) and 20.9 × 106 m3 (Reference Česnulevičius, Šeiriené, Kazakauskas, Baltrūnas, Šinkūnas and KarmazaČesnulevičius and others, 2009). Reference Mernild, Hasholt, Tidwell and KaneMernild and others (2008) tenuously ascribed a further 17.5 × 106 m3 of water as arising from ‘frictional melting of ice as the flood travelled in contact with the glacier together with an input from base flow’.

Table 1. Lake level measurements and calculations used to produce jökulhlaup volumes. Error associated with all measurements is ±0.2 m vertically and 0.1 m horizontally

Between 1985 and 2006, glacier surface elevation in the vicinity of the ice-dammed lake increased by ∼22 ± 5 m (Fig. 3a and b). As the most recent pre-jökulhlaup orthophotograph dates from 2006, these estimates of glacier surface elevation are based on comparisons of oblique field photographs and corresponding natural markers in the field such as lateral moraines, ice-marginal ponds and boulders (Fig. 2). Besides an ice thickness change, an ice-margin advance between 1985 and 2006 is evidenced by field observations of a newly formed push moraine within the ice-dammed lake basin and along the remainder of the local ice margin. While Russell Glacier is known to have advanced between 1968 and 1999 (Reference Knight, Waller, Patterson, Jones and RobinsonKnight and others, 2000), it is interesting to note that the extent of the glacier in the ice-dammed lake basin decreased by 100–180 m between 1985 and 2006 (Fig. 3a and b). In the months immediately following the 2007 draining, we observed that the margin of Russell Glacier advanced ∼50 m into the lake basin. However, no change in ice-margin position was observed following the August 2008 lake draining. The position of the ice margin is important because it controls the relationship between ice-dammed lake level and volume (Fig. 4). Because of ice-margin fluctuations, ice-dammed lake volume for the maximum lake level increased by 8 × 106 m3 from 1985 to 2006 (Fig. 4).

Fig. 4. (a) Stage/volume graph for the ice-dammed lake. The three curves show the stage/volume relationships based on the changes in ice-margin position. The 1985 and 2006 curves are based on digitized ice-margin positions from air photographs, and the 2008 curve is based on GPS measurements. The grey zones indicate changes in drainable volume based on a 10 m advance or retreat of the glacier margin. The 1987 and 1984 volumes were recalculated based on the 1985 curve (Table 1). (b) Volume/peak discharge relationships for floods that route through englacial/subglacial tunnels and those that are triggered by dam failures. The grey ellipse is defined by the error of our calculations, particularly those of peak discharge in which we employ several different methods. Figure 4b is adapted from Reference Walder and CostaWalder and Costa (1996) and Reference Costa and SchusterCosta and Schuster (1988).

Lake elevation was not measured immediately before the 2008 draining. We therefore calculated a lake water recharge in order to estimate lake elevation and volume immediately before the August 2008 jökulhlaup. A seasonal mean refill rate of 0.6–1.0 m3 s−1 is based on discharge measurements of two major proglacial streams between 15 July and 3 August 2008, made by K. Bazeley (personal communication, 2008). A second approach, using our bathymetric model of the ice-dammed lake basin (Fig. 3d) and a measured lake surface rise from 2 to 4 August 2008 of 0.32 ± 0.2 m (from 423.71 m) produces a mean refill rate of 1.29 m3 s−1. We consider this latter recharge rate to be consistent with the proglacial stream discharge since it includes additional meltwater contributions from subglacial melting and ice calving. Photographic evidence from 2 and 17 September 2007 and 22 October 2008 indicates that the post-draining lake surface level was similar for each draining and that subsequent to each draining, refill to the lake basin during the remainder of each respective melt season was negligible.

Ice-dammed lake volume calculated from our new lake bathymetric data (Fig. 3c and d) enabled recalculation of ice-dammed lake volumes for the 1984 and 1987 jökulhlaups, as reported by Reference Sugden, Clapperton and KnightSugden and others (1985) and Reference RussellRussell (1989), respectively. Sugden and others’ (1985) volume estimate of 22.3 × 106 m3 for the 1984 draining has been recalculated as (25.2 ± 0.5) × 106 m3, while Russell’s 1989) estimate of 32–36 × 106 m3 was recalculated as (31.3 ± 0.6) × 106 m3 (Table 1).

Jökulhlaup peak discharge: 1984–2008

The Clague–Mathews (1973) relationship provides peak discharge values of 652, 753, 875 and 416 m3 s−1 for the 1984, 1987, 2007 and 2008 jökulhlaups, respectively (Table 1). Peak discharges calculated using slope/area techniques (Table 2) provide consistently higher estimates of peak discharge. The spillway equation used at the outlet of OL1 (Fig. 1) yielded peak discharges of 2030 and 2774 m3 s−1 for the 1987 and 2007 jökulhlaups, respectively (Table 3). The spillway-derived peak 2007 jökulhlaup discharge agrees well with the average peak discharge calculated from the results of four slope/area techniques, for the same reach, which ranged from 1887 to 2806 m3 s−1 (Table 3). Using the same slope/area techniques, peak discharge at the gauged reach was 1647 m3 s−1 (Table 3). The dramatic attenuation of peak discharge between OL1 spillway and the gauged reach, of ∼40% over just ∼5 km, is attributed to temporary storage within the OL2 basin (Fig. 1).

Table 2. Input data for jökulhlaup peak discharge reconstruction using four variations of the slope/area technique

Table 3. Reconstructed jökulhlaup peak discharge (m3 s−1) for each of the slope/area variants and the weir crest equation

Observations of the ice dam and tunnel entrance

High-spatial-resolution digital orthophotographs taken in 1985 and 2006 illustrate that the position of the tunnel entrance remained fixed, despite changes in the ice-margin position and elevation (Fig. 3a and b). Comparison of these aerial photographs shows net glacier advance of 90–140 m at the tunnel location.

Discussion

We have presented a detailed record of draining of the Russell Glacier ice-dammed lake since 1984 and this constitutes one of the longest records of ice-dammed lake drainage in Greenland. We have documented considerable variation in: (1) the levels to and from which the ice-dammed lake drains; (2) the ice-dammed lake volume; (3) the draining frequency; and (4) the peak discharge with distance downstream.

Controls on jökulhlaup magnitude

Jökulhlaup peak discharge is controlled by the volume of ice-dammed lake water released and lake drainage mechanisms (Reference Tweed and RussellTweed and Russell, 1999; Reference RobertsRoberts, 2005). In recognition of the first of these controls, Walder and Costa’s (1996) modification of the Clague–Mathews relationship was used to predict peak jökulhlaup discharge from the volume of water drained from the ice-dammed lake basin. We found that Walder and Costa’s relationship systematically underpredicts jökulhlaup peak discharge at Russell Glacier, and that the volume to peak discharge relationship for the ice-dammed lake lies between the regression lines for ice tunnel and dam-failure datasets (Fig. 4b). This is because jökulhlaups within the empirical dataset used to define Walder and Costa’s relationship exhibit a more sedate rising stage, which is in line with predicted exponential tunnel expansion as represented by Nye–Clarke equations (Reference RobertsRoberts, 2005). The rising stage of the 1987 Russell Glacier jökulhlaup hydrograph is clearly linear (Reference RussellRussell, 1989, Reference Russell1993b), which reflects more rapid water release and higher peak discharge than predicted by Walder and Costa’s revision of the Clague–Mathews equation. Furthermore, jökulhlaups with a linear rise to peak discharge are subject to a greater degree of downstream discharge attenuation than those with an exponential hydrograph shape (Reference RobertsRoberts, 2005). For these reasons, we argue that Russell Glacier jökulhlaups are best characterized by a hydrograph with a linear rise to peak discharge.

The unusually short englacial/subglacial tunnel length (∼1 km) is an important factor in explaining higher-thanpredicted jökulhlaup peak discharges (Reference Walder and CostaWalder and Costa, 1996). If the ice-dammed lake drained subglacially for 8 km to the Russell Glacier snout, a lower peak discharge would result due to lower conduit enlargement rates. A relatively thin ice dam would also be more prone to flotation, allowing water to exit the lake more rapidly. In 2007 and 2008 the ice-dammed lake drained to a level of 404.9 m, which is ∼10 m above the conduit outlet where the jökulhlaups entered OL1. This suggests the presence of a bedrock lip which controls minimum lake level. Observations of jökulhlaup inlet tunnels that remain in the same place during successive draining events imply that bedrock topography controls both conduit location and form at this location. Jökulhlaup flow through an incised bedrock-walled ‘Nye channel’ will also favour a quicker rise to peak discharge due to the concentration of hydromechanical erosion processes allowing the rapid evacuation of ice from the bedrock channel (Reference RobertsRoberts, 2005).

Jökulhlaup hydrographs are known to attenuate with distance from source because of hydraulic resistance exerted by the proglacial routeways (e.g. Reference CarrivickCarrivick 2007a,b) and therefore complex proglacial topography, such as the interlinked bedrock basins typical of West Greenland, causes a dramatic attenuation of peak discharge downstream (Reference Sugden, Clapperton and KnightSugden and others, 1985). This may partially explain why our slope/area and spillway crest calculations of jökulhlaup peak discharge are so much larger than the peak discharge estimates given by Reference Mernild, Hasholt, Tidwell and KaneMernild and others (2008) and Reference Mernild and HasholtMernild and Hasholt (2009), who utilize stage records ∼35 km downstream, at Kangerlussuaq. Our calculations of peak discharge for the 1987 jökulhlaup display a similar rate of downstream attenuation from the ice-dammed lake, to OL1 and OL2. The gross underestimation of 2007 and 2008 jökulhlaup volumes by Reference Mernild, Hasholt, Tidwell and KaneMernild and others (2008) and Reference Mernild and HasholtMernild and Hasholt (2009) highlights the perils of extrapolating stage/discharge relationships to include higher stage events and the importance of calculating jökulhlaup volume using knowledge of the ice-dammed lake basin.

Jökulhlaup timing and frequency

Reference Russell and de JongRussell and de Jong (1988) and Reference RussellRussell (1989) suggested that the Russell Glacier ice-dammed lake should drain late in the melt season when subglacial/englacial water pressures are more likely to be lower. Thus ingress of lake water to the glacier plumbing system will be facilitated. As the melt season at Russell Glacier typically begins in May, the known draining dates (18 July 1987, 19 August 1984, 31 August 2007 and August 2008) for the Russell Glacier ice-dammed lake (Reference Sugden, Clapperton and KnightSugden and others, 1985; Reference RussellRussell, 1989; Reference Mernild and HasholtMernild and Hasholt, 2009) lend some support to this argument. Ice-dammed lake drainings can be triggered by sudden reductions in subglacial water pressure resulting from reduced meltwater production (Reference Tweed and RussellTweed and Russell, 1999). Interestingly, Reference Mernild and HasholtMernild and Hasholt (2009) noted that the 2007 and 2008 jökulhlaups occurred 4 days after a decrease in mean air temperature.

Precipitation observed by the lead author of this paper at Russell Glacier during the 1987 jökulhlaup was not considered sufficient to offset the decrease in ablation resulting from the reduction in incoming solar radiation (Reference Russell and de JongRussell and de Jong, 1988; Reference RussellRussell, 1989). Similarly precipitation recorded by Reference Mernild and HasholtMernild and Hasholt (2009) in Kangerlussuaq before the 2007 jökulhlaup is not thought to be significant to triggering of the ice-dammed lake drainage. Reference Van de Wal and RussellVan de Wal and Russell (1994) identified a non-convective rainfall event in the 1991 discharge hydrograph record from Russell Glacier; however, ablation-controlled discharge variations provide the greatest overall impact on the meltwater runoff rate. Although reduced subglacial/englacial meltwater pressure conditions may provide more favourable conditions for lake drainage, the specific timing or triggering threshold for a jökulhlaup during the melt season is likely to reflect the year-to-year variations in melt volume seasonal evolution of the subglacial drainage system (Reference TedescoTedesco, 2007; Reference Mernild and HasholtMernild and Hasholt, 2009).

Draining of the Russell Glacier ice-dammed lake between the 1950s and 1987 is considered to have occurred every 2–3 years, based on evidence from aerial photographs, sedimentary data and lake refill time (Reference GordonGordon, 1986; Reference RussellRussell, 1989, Reference Russell1993a). Reference Mernild and HasholtMernild and Hasholt (2009) suggest that the ice-dammed lake drained in consecutive years in 1983 and 1984, thereby mirroring the 2007 and 2008 events. Although Reference Sugden, Clapperton and KnightSugden and others (1985) suggest that the ice-dammed lake may drain annually, their argument for a jökulhlaup in 1983 was based on wash limit evidence of a jökulhlaup of equivalent or greater magnitude to their observed 1984 flood. The 1984 jökulhlaup had a volume of (25.2 ± 0.5) × 106 m3, which is twice the volume of the 2008 jökulhlaup, thus making it highly unlikely that the lake drained in 1983. We therefore consider the 2007 and 2008 jökulhlaups to be the first recorded consecutive annual draining events from the Russell Glacier ice-dammed lake.

The 2007 jökulhlaup was the largest ever recorded from this ice-dammed lake. The 2008 jökulhlaup was one-third the volume drained in 2007. To explain the occurrence of two such different jökulhlaups from the same ice-dammed lake in close succession, we invoke different draining and triggering mechanisms. We suggest that the subglacial passage of the 2007 jökulhlaup weakened the ice dam sufficiently to allow the 2008 draining to occur at a much lower lake level. It is possible that much of the subglacial conduit remained open between the two events. It is also possible that the lake did not re-seal after the 2007 draining. A substantial accumulation of naled (aufeis) ice was observed in May 2008, directly in front of the 2007 jökulhlaup conduit outlet, indicating a steady feed of water from the conduit through the winter months. Discharge of water observed from the tunnel outlet in late May 2008 may also have been from leakage of the ice-dammed lake. Observations of the 2007 jökulhlaup tunnel inlets in late May 2008 show that they were covered by ice cliff collapse breccia. Similarly, the 2008 tunnel inlets were observed to collapse within 2 months of the ice-dammed lake draining. It is feasible that rising ice-dammed lake levels during the 2008 melt season enabled the flotation of ice cliff collapse debris from the conduit entrances, permitting the lake to drain.

The Russell Glacier ice-dammed lake clearly experiences two different modes of draining associated with different draining mechanisms, frequencies and flood magnitudes. The fact that the ice-dammed lake did not drain in 2009 suggests that the lake is sealed and that the next jökulhlaup will occur when the lake has filled sufficiently to exert sufficient hydraulic pressure to allow connection with the subglacial drainage system.

Ice-dammed lake/glacier interactions

Although observations of ice-dynamic responses to lake draining have been made (Reference Sugden, Clapperton and KnightSugden and others, 1985; Reference WalderWalder and others, 2006; Reference Mayer, Lambrecht, Hagg, Helm and ScharrerMayer and others, 2008), detailed consideration of lake volume, lake levels and ice-margin position for multiple jökulhlaups from the same system is much rarer (Reference Guðmundsson, Björnsson and PálssonGuðmundsson and others, 1995; Reference Roberts, Pálsson, Guðmundsson, Björnsson and TweedRoberts and others, 2005; Reference Ng and LiuNg and Liu, 2009). We have demonstrated that following the 2007 draining, glacier advance into the Russell Glacier ice-dammed lake basin reduced the lake basin volume. Our data are compatible with observations of Reference Sugden, Clapperton and KnightSugden and others (1985) for the same ice-dammed lake. They reported glacier margin advance following the 1984 jökulhlaup. Jökulhlaup volume and peak discharge therefore decreased. Such feedbacks between ice-dammed lakes and ice-margin position will produce progressive decreases in jökulhlaup magnitude within a jökulhlaup cycle.

Controls on the jökulhlaup cycle at Russell Glacier

The fact that the 2007 jökulhlaup is the largest documented from this site is consistent with the onset of a new cycle of draining, as envisaged by Reference Evans and ClagueEvans and Clague (1994). However, we present field data from a more stable ice-dammed lake configuration than that described by Evans and Clague, whose model concentrates on a piedmont setting where glacier margin position, lake extent and lake volume fluctuate relatively quickly over time during glacier advance and retreat. At Russell Glacier the first jökulhlaup cycle stopped in 1987 even though the lake was still full. Ice-dammed lake drainage at Russell Glacier is dependent not only upon ice-margin advance and retreat, but also upon the responses of ice thickness and glacier hydrology to subtle changes in glacier mass balance. This serves to emphasize two points. Firstly, this is a modern-day example of cyclical ice-dammed lake drainage events seen during the Little Ice Age, for example in Iceland (Reference ThórarinssonThórarinsson, 1939). Secondly, the occurrence of cycles of jökulhlaups from ice-dammed lakes can be generated by climate change.

Conclusions and Wider Implications

Ice-dammed lake drainage at Russell Glacier has renewed after 20 years of dormancy, between 1987 and 2007. We find that ice-margin advance/thickening and retreat/thinning are key factors controlling the occurrence and character of jökulhlaups at this site. Specifically, at Russell Glacier there was a period of ice-margin advance from 1987 to 1999 followed by recession (∼50 m) and ice surface lowering (∼10 m), i.e. ice thinning. Draining of the same lake in 2008 suggests that the 2007 jökulhlaup was the first in a new cycle of ice-dammed lake drainage (Reference Evans and ClagueEvans and Clague, 1994; Clague and Evans 1997). The 2007 jökulhlaup is the largest documented at this site, and this fact is consistent with the model of Reference Evans and ClagueEvans and Clague (1994). We find that reduced lake volumes, and thus lower jökulhlaup peak discharges, can be produced by localized ice-margin advance and/or glacier thinning. Our calculations of lake volume drained and peak discharge argue for a non-exponential model for the drainage of the ice-dammed lake, and thus a mechanism that is determined by a relatively thin ice dam, a short bedrock-controlled subglacial tunnel and hydromechanical erosion of glacier ice. We reconstruct a 40% attenuation in peak discharge over just ∼5 km due to temporary flood water storage within a series of bedrock-controlled proglacial lake basins. Correct identification of the volume of an ice-dammed lake is crucial for providing accurate estimates of the total volume of meltwater runoff, which goes into temporary storage at the ice-sheet margin. Using Mernild and Hasholt’s (2009) discharge values, drainage of the relatively small ice-dammed lake at Russell Glacier contributes 2–3% of the annual runoff from the entire Kangerlussuaq basin. It is clear that large ice-dammed lakes, which are numerous in West Greenland, may prevent the direct delivery of significant volumes of meltwater to the oceans over annual to decadal timescales.

Acknowledgements

We thank K. Petersen for logistic support. J.L.C. received financial support from the School of Geography academic development fund. We also acknowledge support from the US National Science Foundation through grant ARC-0612533. We thank M. Roberts and J. Clague for constructive reviews of the manuscript, and M.T. Guðmundsson for editorial review and advice.

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Figure 0

Fig. 1. Location of field area within Greenland and in relation to the Kangerlussuaq and Kellyville GPS site (KELY). The ice-dammed lake, outlet lake 1 (OL1) and outlet lake 2 (OL2) are shown in relation to the northern margin of Russell Glacier. The ice-dammed lake drains through an englacial/subglacial tunnel, indicated by a dashed arrow, for a distance of ∼1 km, routing jökulhlaups into OL1. Proglacial jökulhlaup peak discharge reconstructions were undertaken at the spillway between OL1 and OL2 and at the 1987 gauged reach (labelled ‘Gauge’).

Figure 1

Fig. 2. Ice-dammed lake at the northern margin of Russell Glacier, on 21 July 1987 and 24 May 2008. Both photographs were taken immediately after a jökulhlaup, permitting comparison between the lake level drops. Arrows indicate common points, and are used for examining ice-margin position and thickness.

Figure 2

Fig. 3. Recent visual history of ice-dammed lake dynamics. (a) 1985 aerial photograph by Danish National Survey and Cadastre shows low lake level, smaller lake surface area and thinner ice. (b) 2006 aerial photograph by ARTEK shows maximum lake level, larger lake volume and thicker ice. Maximum lake level is controlled by a proglacial bedrock spillway which drains into OL1. (c) Tracks of a kinematic dGPS survey undertaken in February 2008 to interpolate lake basin bathymetry. (d) Lake bathymetric model with contours at 5 m intervals. Maximum lake level illustrated is 453.7 m. Lake levels were measured in May 2008.

Figure 3

Table 1. Lake level measurements and calculations used to produce jökulhlaup volumes. Error associated with all measurements is ±0.2 m vertically and 0.1 m horizontally

Figure 4

Fig. 4. (a) Stage/volume graph for the ice-dammed lake. The three curves show the stage/volume relationships based on the changes in ice-margin position. The 1985 and 2006 curves are based on digitized ice-margin positions from air photographs, and the 2008 curve is based on GPS measurements. The grey zones indicate changes in drainable volume based on a 10 m advance or retreat of the glacier margin. The 1987 and 1984 volumes were recalculated based on the 1985 curve (Table 1). (b) Volume/peak discharge relationships for floods that route through englacial/subglacial tunnels and those that are triggered by dam failures. The grey ellipse is defined by the error of our calculations, particularly those of peak discharge in which we employ several different methods. Figure 4b is adapted from Walder and Costa (1996) and Costa and Schuster (1988).

Figure 5

Table 2. Input data for jökulhlaup peak discharge reconstruction using four variations of the slope/area technique

Figure 6

Table 3. Reconstructed jökulhlaup peak discharge (m3 s−1) for each of the slope/area variants and the weir crest equation