Introduction
The Antarctic Ice Sheet is losing ice at an accelerated rate and has contributed 7.6 ± 3.9 mm to global sea level rise between 1992 and 2017 (Shepherd and others, Reference Shepherd2018). Much of the mass loss from Antarctica has occurred via ice sheet thinning at glacial margins and calving events on ice shelves (e.g., Greene and others, Reference Greene, Gardner, Schlegel and Fraser2022). These calving events are believed to be influenced by supraglacial melt. Recent work has identified and mapped over 65 000 supraglacial lakes along the margin of the East Antarctic Ice Sheet (EAIS), some of which can induce hydro-fracturing near grounding lines (Stokes and others, Reference Stokes, Sanderson, Miles, Jamieson and Leeson2019). While the occurrence and variability of supraglacial meltwater is largely believed to be due to synoptic scale climatological patterns (Donat-Magnin and others, Reference Donat-Magnin2020), little is documented about modern warming events and meltwater storage for the Transantarctic Mountains (TAM).
Evidence of warming and increased meltwater production has been documented at lower latitudes along the TAM. For example, a cooling trend observed 1986–2001 ended in the McMurdo Dry Valleys (~77.6° S) with a ‘flood year’ during the austral summer of 2001–2002 (Barrett and others, Reference Barrett2008; Gooseff and others, Reference Gooseff2017). Enhanced melt of alpine and piedmont glaciers resulted in substanstive increases in stream flow and lake level rise, which freshened the hypolimnion of the lakes and effectively ‘reset’ a decade of cryoconcentration (Barrett and others, Reference Barrett2008). This flood year was the start of a regime shift toward elevated summer meltwater generation, lake ice thinning, and changes in ecosystem structure that have persisted for over a decade (Gooseff and others, Reference Gooseff2017). Farther south (~250 km) along the Darwin Glacier, lake levels for proglacial Lake Wilson increased by 20 m between 1975 and 1993 (Webster and others, Reference Webster, Hawes, Downes, Timperley and Howard-Williams1996). The flux of meltwater adversely affected lake biological communities, with primary production limited to the upper mixed layer (Webster and others, Reference Webster, Hawes, Downes, Timperley and Howard-Williams1996). Lake Wilson was believed to be the southernmost dry valley lake, until the Shackleton Glacier region lakes were identified and described (Elliot and others, Reference Elliot, Collinson and Green1996; Dengler, Reference Dengler2013). In this work, we provide both imagery and geochemical evidence for a dynamic hydrologic system in high elevation, high southern latitude dry valleys. Our goal was not a comprehensive analysis of all high southern latitude lakes, but instead to focus on two previously identified systems for which remote sensing and in situ data could be interpreted, and to provide recommendations for future work.
Study site
The Shackleton Glacier is a major outlet glacier of the EAIS and flows ~130 km south to north through the Queen Maud Mountains of the Central Transantarctic Mountains. To the south, east, and west of the glacier, dry valleys are present among the mountain peaks. Two of these valleys are the focus of this work: colloquially known as Thanksgiving Valley and Heekin Valley (Fig. 1).
Sampling locations of lakes near Mt. Heekin (‘Heekin Valley’) and Thanksgiving Valley along the Shackleton Glacier, Antarctica. The locations for water sampling are noted in each inset. All images are visible panchromatic WorldView-1, -2, and -3 images acquired with assistance from the Polar Geospatial Center.
Thanksgiving Valley (−84.9164, −177.0218) is located near the intersection of Shackleton Glacier and Mincey Glacier, a smaller tributary. Rogue and Butters glaciers also flow into the valley and can contribute to glacial runoff. Thanksgiving Valley is nearly perpendicular to Shackleton Glacier and trends SW-NE, at about 3.5 km length and 1.5 km width and has ridges to the north and south. Six ponds and lakes have been noted in the valley: Thanksgiving Lake – the largest, Bald Pond – the smallest, Speckled Pond, Baxter Pond, Lake Abol, and Ghost Lake (see Dengler, Reference Dengler2013). Lake Abol and Ghost Lake are in the deepest portion of the valley and are separated from Shackleton Glacier by a large saddle. Dengler (Reference Dengler2013) noted that Lake Abol is fed by meltwater from Butters Glacier and a local snowpack. It occasionally spills over and feeds Ghost Lake. Algal samples taken near Ghost Lake had radiocarbon ages of approximately 10 ka and the meteoric 10Be estimated exposure duration near Lake Abol suggests that the surface has an exposure duration of approximately 250 ka (Dengler, Reference Dengler2013; Diaz and others, Reference Diaz2021b).
Mt. Heekin is located near the intersection of Baldwin and Shackleton glaciers. A large saddle separates a deep valley, informally termed ‘Heekin Valley’, from Mincey Glacier. Meltwater from a tongue of Baldwin Glacier and higher elevation snowpack pools at the valley floor to form a dry-valley lake that occasionally spills over to form lakes at slightly lower elevations. Elliot and others (Reference Elliot, Collinson and Green1996) identified modern algal mats near the Heekin lakes and mats near Shackleton Glacier were later dated to a maximum of approximately 3000 yrs (Dengler, Reference Dengler2013). The lakes at Mount Heekin are located about 990 m a.s.l. and the lakes at Thanksgiving are at approximately 1080 m a.s.l., which is significantly higher elevation than the McMurdo Dry Valleys lakes which are less than 50 m a.s.l.
Methods
Water samples were collected from melted lake moats at both Lake Abol and Ghost Lake. Samples were collected for ions and nutrients (Na+, K+, Ca2+, Mg2+, Cl−, PO43−, NO3− + NO2− and NH3), and stable water isotopes (δ18O and δ2H). All samples were filtered immediately upon collection using a clean plastic syringe and passed through a 0.45 μm nylon syringe filter. The ion and nutrient samples were frozen upon return to Shackleton camp (within three hours). The water isotope samples were filled and capped with no headspace and kept chilled (~+4°C) until analysis.
The aqueous geochemistry analytical techniques used here are similar to those reported by Diaz and others (Reference Diaz2021a) and Welch and others (Reference Welch2010). In summary, the cations were measured on a PerkinElmer Optima 8300 Inductively Coupled Plasma-Optical Emission Spectrometer (ICP-OES), anions on a Dionex ICS-2100 ion chromatograph, nutrients on a Skalar San++ Automated Wet Chemistry Analyzer, and water isotopes on a Picarro Wavelength Scanned-Cavity Ring Down Spectroscopy Analyzer Model L1102-I at The Ohio State University. Accuracy was typically better than 5%, as determined by the NIST 1643e external reference standard and the 2015 USGS interlaboratory calibration standard (M-216). δ18O and δ2H measurements are reported with respect to Vienna Standard Mean Ocean Water.
Satellite images were collected with the assistance of the Polar Geospatial Center and included a variety of satellite products, namely visible panchromatic WorldView-1, -2, and -3. No georeferenced images could be analyzed prior to 2009 for either valley due to the high occurrence of clouds and gaps in data. Additionally, deep shadows at the valley floors during summertime eliminate the possibility of using digital elevation models to estimate depth, and subsequently volume, of the lakes in Thanksgiving and Heekin Valleys. Images were processed via ESRI ArcGIS Pro 2.1 and areas were measured by hand by creating polygons using internal applications.
Results and discussion
Heekin Valley lakes
In 1996, three small ponds were identified and sampled in Heekin Valley: one in contact with the glacial tongue (~700 m2), and two isolated ponds on the valley floor further away (~9700 m2 and ~17 500 m2) (Elliot and others, Reference Elliot, Collinson and Green1996). Elliot and others (Reference Elliot, Collinson and Green1996) also identified a dried pond bed near one of the isolated ponds (Fig. 2b). An archived image flyover near Mt. Heekin in 1960 indicates that the ponds in Heekin Valley had not drastically changed in area when the ponds were sampled in 1996 (Elliot and others, Reference Elliot, Collinson and Green1996), suggesting that this environment may have been essentially static for approximately 40 years, though lake levels were certainly higher in the more distant past (Dengler, Reference Dengler2013; Diaz and others, Reference Diaz2021b). We visited the site again a decade later in December 2007. Aerial images show that the original three ponds and the dry pond bed had filled and merged into a single large lake (Fig. 2c). When we visited the site approximately another decade later, a second, subsidiary lake had formed due to spillover of the first, primary lake. We observed later stages of the subsidiary lake formation in satellite imagery. The subsidiary lake had begun forming sometime after 2007 but prior to 2009. Between 2009 and 2018, water can be seen in a stream flowing over a ridge to feed the subsidiary lake, which increased in area from approximately 11 500 m2 to 21 300 m2 over this time (Fig. 3). Water can also be seen in a stream filling the primary lake from the glacier tongue and from a small stream draining glacial ice and snowpack higher up along the valley wall.
Timeseries of the Mt. Heekin ponds and lakes from 1960 to 2017. The aerial image (TMA 786 33R 0052) in (a) and ground image in (b) show the three separate ponds (oriented south), while (c) and (d) are aerial images showing that the original ponds merged and a subsidiary lake formed (oriented north). The 1996 image (b) is from Elliot and others (Reference Elliot, Collinson and Green1996), with the black arrow indicating a dried pond bed.
Growth of the subsidiary Heekin Valley lake, as shown by satellite images from PGC.
These observations are validated by water stable isotope measurements from the primary and largest lake. When δ18O and δ2H were plotted along with generalized local meteoric water lines (calculated from published data (Helsen and others, Reference Helsen, van de Wal and van den Broeke2007; Masson-Delmotte and others, Reference Masson-Delmotte2008)) for both ice and snow, the Heekin lake values suggest that the majority of water is derived from glacial melt that has been ponded and then evaporated (Fig. 4). In terms of the water-soluble salt and nutrient geochemistry, concentrations of PO43− decreased from the three-lake average of ~0.31 μM to 0.10 μM from 1996 to 2018 (Table 1). NO3− values increased, which is unsurprising given the high concentrations of nitrate salts in the region sourced from atmospheric deposition (Diaz and others, 2021a, Reference Diaz2020).
Water stable isotopes of the Heekin and Thanksgiving valley lakes. The local meteoric water lines, calculated from published data (Helsen and others, Reference Helsen, van de Wal and van den Broeke2007; Masson-Delmotte and others, Reference Masson-Delmotte2008), for ice and snow are shown.
Water-soluble ion concentrations from the Heekin and Thanksgiving (TGV) valley lakes (this study, 2018) and the data reported by Elliot and others (Reference Elliot, Collinson and Green1996) from Mt. Heekin
BDL represents data below detection limit.
Thanksgiving Valley lakes
Higher temporal resolution images were analyzed for Thanksgiving Valley compared to Heekin Valley, as we were able to attain nearly yearly and sometimes sub-annual resolution images to understand the lake filling and drainage mechanisms from 2009 to 2020. Lake Abol does not significantly change in size until it overfills and spills into Ghost Lake. In 2009 and 2010, Ghost Lake was completely dry but filled by the time the next image was taken in 2013. From 2014 to 2020, the lake slowly decreased in area until 2018, when it filled again and then evaporates (Fig. 5). Lake Abol receives most of its water from Butters and Rogue glaciers, as evidenced by the stable water isotope composition; the water is glacially sourced and evaporated.
Timeseries of the Thanksgiving Valley lakes from 2009 to 2020 (a). The subsidiary Heekin lake is plotted for comparison. Aerial images showing the disappearance (b), growth (c), and evaporation (d) of Ghost Lake.
The water-soluble ion concentrations for the Abol and Ghost lakes are comparable with those from Heekin. However, Ghost generally has the highest concentrations of conservative ions and, in particular, has approximately twice the amount of sodium and chloride as Abol, which is expected given that the lake was evaporating in 2018. Concentrations of PO43− were below the analytical detection limit for Ghost Lake and ammonia concentrations were the highest. Any P entering these lakes is derived from the chemical weathering of the soils as the glacial meltwaters flow over and through them, as the soils in the region have not been wetted previously for several thousand years (Diaz and others, Reference Diaz2021b). This P is consumed via algal growth, thus lowering its concentration below our analytical detection limit. The system is likely P limited (Barrett and others, Reference Barrett2007), where even bioavailable N (e.g., ammonia) could accumulate. We did not observe any algal mat, though Dengler (Reference Dengler2013) noted dried mats along paleolake shores. No analysis has been done to determine the microbial composition in any of these lakes, but our preliminary work yielded no diatom counts.
Quasi-synchronous widespread melting
We compared the timing of lake filling for Heekin and Thanksgiving valleys with flow records from the Onyx River in the McMurdo Dry Valleys ~1000 km NW (Fig. 6). The Onyx River has the longest flow record of dry valley streams, dating back to 1970, and can be used as a sentinel for hydrologic changes (Gooseff and others, Reference Gooseff, McKnight, Doran and Berry Lyons2007). Our comparison indicates that during the period from 1975 to 1993 when Lake Wilson deepened by 20 m, there were some smaller pulses of meltwater flow for the Onyx. The Heekin lakes merged between 1996 and 2006, during which the flood year in the McMurdo Dry Valleys occurred (2002). There was another meltwater pulse in the Onyx record in 2009, which coincided with the formation of the subsidiary lake in Heekin Valley, and the elevated river flow from 2012–2018 was during a period when Ghost Lake filled and the subsidiary Heekin lake grew. While rudimentary, our comparison of these records suggests that increased glacier meltwater generation was quasi-synchronous between the McMurdo Dry Valleys and the Central Transantarctic Mountains. In other words, regional warming and concomitant hydrological changes in the Central Transantarctic Mountains might be more widespread and dynamic than previously thought (Jones and others, Reference Jones2019).
Timing of lake growth and formation in the Central Transantarctic Mountains in the context of flow (discharge) from the Onyx River in the McMurdo Dry Valleys. Flow data were compiled from the McMurdo LTER (DOI: 10.6073/pasta/4370a8c48ad3b1f5f1de7aa43155e13c).
Conclusions and recommendations
No data from long-term weather stations are available in the TAM and studies on the influence of summer temperature variations and the potential generation of surface meltwater in East Antarctica are limited to coastal regions (e.g., Stokes and others, Reference Stokes, Sanderson, Miles, Jamieson and Leeson2019). As a result, the hydrologic system in the Central Transantarctic Mountains is thought to be fairly static and evidence of active meltwater generation has been anecdotal (Bell and others, Reference Bell, Banwell, Trusel and Kingslake2018). In this study, we analyzed two lake systems in the Shackleton Glacier region which, to our knowledge, are the southernmost dry valley lakes. However, we speculate that there are additional lakes in the Central Transantarctic Mountains that have yet to be formally documented.
Satellite imagery and aerial photographs show that the lakes in Heekin Valley have grown in size and merged, filling a previously dry pond bed, and the lakes in Thanksgiving Valley have grown, evaporated, and overflowed through the last 30 years. The water is primarily derived from glacial melt, and the water-soluble ion geochemistry suggests that the lakes may have active modern biological communities. Documented pulses of glacial meltwater in the Shackleton Glacier region appear to coincide with long-term climate warming and meltwater pulses 1000 km away in the McMurdo Dry Valleys. It is possible warming trends are widespread throughout the TAM and dry valleys can provide evidence for past and current meltwater storage.
These high elevation, high southern latitude lakes may be our only indicators of warming and glacier melting near the Antarctic interior, yet they are understudied. Our data may be used to verify Climate Reanalysis datasets (Carter and others, Reference Carter, Leeson, Orr, Kittel and van Wessem2022). Additional studies are needed focusing both on remote sensing: to identify and characterize additional meltwater lakes at high southern latitudes, quantify rates of glacier melting, and infer weather and climatic changes, and in situ analysis: to understand the sources of meltwater generation and mechanisms of alteration, rates of chemical weathering, and changes in soil and lake habitability.
Acknowledgements
We thank the United States Antarctic Program (USAP), Antarctic Science Contractors (ASC), and Petroleum Helicopters Inc. (PHI) for logistical and field support. We are especially grateful to Michael Cloutier (PGC) for his help in acquiring satellite imagery from the Shackleton Glacier region, S. Welch for help with the geochemical measurements, and D. Smith for help with the water isotope measurements. Geospatial support for this work was provided by the Polar Geospatial Center under NSF-OPP awards 1043681 and 1559691. This work was supported by NSF-OPP awards 1341631 and 1341629 to WBL and BJA, and NSF-GRFP 60041697 awarded to MAD.
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