Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-26T22:00:28.084Z Has data issue: false hasContentIssue false

The U-Pb detrital zircon signature of West Antarctic ice stream tills in the Ross embayment, with implications for Last Glacial Maximum ice flow reconstructions

Published online by Cambridge University Press:  13 November 2014

Kathy J. Licht*
Affiliation:
Indiana University-Purdue University Indianapolis, Department of Earth Sciences, 723 West Michigan Street, Indianapolis, IN 46202, USA
Andrea J. Hennessy
Affiliation:
Indiana University-Purdue University Indianapolis, Department of Earth Sciences, 723 West Michigan Street, Indianapolis, IN 46202, USA
Bethany M. Welke
Affiliation:
Indiana University-Purdue University Indianapolis, Department of Earth Sciences, 723 West Michigan Street, Indianapolis, IN 46202, USA
Rights & Permissions [Opens in a new window]

Abstract

Glacial till samples collected from beneath the Bindschadler and Kamb ice streams have a distinct U-Pb detrital zircon signature that allows them to be identified in Ross Sea tills. These two sites contain a population of Cretaceous grains 100–110 Ma that have not been found in East Antarctic tills. Additionally, Bindschadler and Kamb ice streams have an abundance of Ordovician grains (450–475 Ma) and a cluster of ages 330–370 Ma, which are much less common in the remainder of the sample set. These tracers of a West Antarctic provenance are also found east of 180° longitude in eastern Ross Sea tills deposited during the last glacial maximum (LGM). Whillans Ice Stream (WIS), considered part of the West Antarctic Ice Sheet but partially originating in East Antarctica, lacks these distinctive signatures. Its U-Pb zircon age population is dominated by grains 500–550 Ma indicating derivation from Granite Harbour Intrusive rocks common along the Transantarctic Mountains, making it indistinguishable from East Antarctic tills. The U-Pb zircon age distribution found in WIS till is most similar to tills from the west-central Ross Sea. These data provide new specific targets for ice sheet models and can be applied to pre-LGM deposits in the Ross Sea.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© Antarctic Science Ltd 2014

Introduction

Understanding local landscape modifications by glaciers and the global impacts of dynamic changes in ice sheets have occupied efforts of earth scientists for centuries. The West Antarctic Ice Sheet (WAIS), in particular, has long been considered susceptible to changes in sea level and ocean temperature variations resulting in more dynamic behaviour than the East Antarctic Ice Sheet (EAIS), which has a smaller proportion of its basal area below sea level (e.g. Joughin & Alley Reference Joughin and Alley2011). A new analysis of the past several decades of data shows that central West Antarctica has become one of the fastest warming areas of the planet (Bromwich et al. Reference Bromwich, Nicolas, Monaghan, Lazzara, Keller, Weidner and Wilson2013). On longer timescales, the geological record provides an important archive of the ice sheet’s response to warming over the past several hundred thousand to millions of years. Various studies have suggested that the WAIS fluctuated in synchrony with orbital forcings and even ‘collapsed’ at various times throughout its history (e.g. Naish et al. Reference Naish, Powell and Levy2009, Pollard & DeConto Reference Pollard and DeConto2009). Higher global sea levels during previous late Quaternary interglacials found in geological records from Australia to Bermuda are often attributed a smaller WAIS (e.g. O’Leary et al. Reference O’Leary, Hearty, Thompson, Raymo, Mitrovica and Webster2013). Reconstructions of EAIS and WAIS extent, based on direct geological evidence, come from sediment cores and geophysical surveys on the Antarctic continental margin where the ice sheets have left their imprints (e.g. Anderson et al. Reference Anderson, Conway, Bart, Witus, Greenwood, McKay, Hall, Ackert, Licht, Jakobsson and Stonein press).

A variety of challenges hinder the interpretation of ice sheet history from sedimentary records. In Antarctica, determining the chronology of offshore glacial deposits has been a particularly persistent problem (e.g. Andrews et al. Reference Andrews, Domack, Cunningham, Leventer, Licht, Jull, DeMaster and Jennings1999), but advances in analytical techniques have provided new opportunities to more accurately map out past ice extent and flow directions. Shipboard and satellite remote sensing techniques have revealed paradigm changing geomorphic features. For example, multibeam swath bathymetry surveys show that the continental shelf around Antarctica has been sculpted into a complex mosaic of linear ridges and troughs, drumlins, and moraines once thought absent from Antarctica (e.g. Shipp et al. Reference Shipp, Anderson and Domack1999). Similarly, provenance studies that reveal the path of past ice sheet flow and the source of ice-rafted debris to the Southern Ocean have advanced from studies of sand and pebble petrography to isotopic (Sm-Nd, Pb-Pb) and geochronological tools (U-Pb, Ar-Ar) (e.g. Farmer et al. Reference Farmer, Licht, Swope and Andrews2006, Pierce et al. Reference Pierce, Williams, van de Flierdt, Hemming, Goldstein and Brachfeld2011, Flowerdew et al. Reference Flowerdew, Tyrrell and Peck2013, Licht & Palmer Reference Licht and Palmer2013). These tools are particularly useful for fingerprinting debris from parts of the ice sheet whose subglacial geology is distinctive. For example, the differing geological histories of Marie Byrd Land and the Transantarctic Mountains (TAM), which flank the West Antarctic rift basin over which the WAIS flows, should provide erosional products that can be used to identify and trace ice sheet flow over each area. This paper reports the results from a study of detrital zircons from Ross embayment tills and shows that grains from West Antarctica have characteristic age populations, providing an important new tracer of the WAIS. Such tracers provide an essential tool to help discriminate between sediments deposited beneath ice flowing from East and West Antarctica.

Setting and background

East and West Antarctica are divided by the 3500 km long TAM. In the Ross embayment, the majority of the EAIS flows toward the coast via outlet glaciers cutting through the TAM, whereas most ice draining into the Ross Sea from West Antarctica flows via fast moving ice streams unconstrained by exposed bedrock. Some ice streams, such as Kamb (KIS) and Bindschadler (BIS), originate entirely in West Antarctica, whereas the Mercer and Whillans ice stream catchments extend into East Antarctica (Fig. 1), but are considered key dynamic features of the WAIS.

Fig. 1 Relief map of Ross embayment area of study from GeoMapApp. Yellow dots show sample locations. B=Beardmore Glacier, BIS=Bindschadler Ice Stream, By=Byrd Glacier, CRS=central Ross Sea, Ed VII=Edward VII Peninsula, ERS=eastern Ross Sea, FR=Ford Ranges, KIS=Kamb Ice Stream, L=Law Glacier, McIS=MacAyeal Ice Stream, MIS=Mercer Ice Stream, N=Nimrod Glacier, OR=Ohio Range, R=Reedy Glacier, S=Scott Glacier, WIS=Whillans Ice Stream, WM=Whitmore Mountains, WRS=western Ross Sea.

The history of ice sheet development and fluctuations can be challenging to reconstruct where repeated ice advances erase, rework and/or bury the record from previous advances. Glacial deposits from the last glacial maximum (LGM) are well characterized in the Ross embayment and show that grounded ice reached the outer continental shelf in the eastern and central Ross Sea, but not in the western Ross Sea (see summary in Anderson et al. Reference Anderson, Conway, Bart, Witus, Greenwood, McKay, Hall, Ackert, Licht, Jakobsson and Stonein press). Till deposited on the continental shelf has been shaped into mega-scale glacial lineations that typically parallel the sea floor troughs and are interpreted to represent substrate deformation associated with streaming ice (e.g. Shipp et al. Reference Shipp, Anderson and Domack1999). Such lineations reflect ice flow direction and some cross-cutting patterns are observed in eastern Ross Sea floor troughs (Mosola & Anderson Reference Mosola and Anderson2006).

The modern WAIS occupies a portion of the West Antarctic rift basin, which is characterized by muted basin-parallel ridges and troughs that contain sediment up to 400–800 m thick (Peters et al. Reference Peters, Anandakrishnan, Alley, Winberry, Voight, Smith and Morse2006). The subglacial sediments are interpreted to have varying water content over space and time, and thus have dynamic interactions with the ice sheet base that impact ice stream flow into the Ross Sea (e.g. Christoffersen et al. Reference Christoffersen, Tulaczyk and Behar2010). The West Antarctic basin formed in the mid-Cretaceous through the Cenozoic with horizontal displacement totalling several hundred kilometres between Marie Byrd Land and East Antarctica (Fig. 1) (Winberry & Anandakrishnan Reference Winberry and Anandakrishnan2004). Major extension began in the Cretaceous c. 105 Ma and continued throughout the Cenozoic, with 150 km of extension recorded in the Eocene–Oligocene (e.g. Siddoway Reference Siddoway2008). During the Eocene, the TAM were being uplifted relative to West Antarctica and shed sediments into the West Antarctic basin (e.g. Siddoway Reference Siddoway2008).

The major rock outcrop exposures of West Antarctica are in Marie Byrd Land and consist of the Palaeozoic Swanson Formation, magmatic rocks spanning the Devonian to mid-Cretaceous, and Cenozoic volcanic rocks (Tingey Reference Tingey1991). Late Cretaceous erosion produced the Marie Byrd Land dome (LeMasurier & Landis Reference LeMasurier and Landis1996). This feature trends east–west, roughly parallel to the Marie Byrd Land coast (Fig. 1) (LeMasurier & Landis Reference LeMasurier and Landis1996, Winberry & Anandakrishnan Reference Winberry and Anandakrishnan2004) and probably shed sediment southward into the initial lowlands of the forming West Antarctic basin. Most of the pre-Cenozoic rock units contain zircons that have been dated using U-Pb and these units are briefly described below to characterize possible sources of detrital zircons in West Antarctic glacial till.

The immature meta-sediments of the Swanson Formation, which outcrop in the Ford Ranges and Edward VII Peninsula (Fig. 1), have U-Pb ages of c. 500–600 Ma (Fig. 2) and a smaller population 800–1000 Ma (Pankhurst et al. Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998). The Swanson Formation was intruded by the Ford Granodiorite which was emplaced c. 375 Ma; ages from associated granites and migmatites span c. 335–375 Ma (Fig. 2) (Pankhurst et al. Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998, Siddoway & Fanning Reference Siddoway and Fanning2009, Korhonen et al. Reference Korhonen, Saito, Brown, Siddoway and Day2010). The Byrd Coast Granite was emplaced following the Ford Granodiorite, with ages of 95–124 Ma (Pankhurst et al. Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998, Siddoway Reference Siddoway2008). Igneous activity in the mid-Cretaceous continued with granite emplacement along the Ruppert and Hobbs coasts 101–110 Ma (Mukasa & Dalziel Reference Mukasa and Dalziel2000) and the Ford Ranges to Edward VII Peninsula 95–120 Ma (e.g. Weaver et al. Reference Weaver, Adams, Pankhurst and Gibson1992, Korhonen et al. Reference Korhonen, Saito, Brown, Siddoway and Day2010) (Fig. 2).

Fig. 2 Diagram shows the relative frequency of Phanerozoic U-Pb zircon ages from dominant bedrock types surrounding the study area. Darker shades of grey indicate a higher frequency of grains relative to the total distribution from that rock type. BCG +=Byrd Coast Granite plus others described in text, ES=Eocene sandstone, FG +=Ford Granodiorite plus others described in text, GHI=Granite Harbour Intrusives, SF=Swanson Formation.

On the southern margin of the West Antarctic rift basin, exposed rocks of the TAM have also been dated using U-Pb of zircons. Those described here are the most widespread rock units along the southern TAM. The Granite Harbour Intrusives extend along much of the mountain front and U-Pb ages for this complex group of rocks are typically 485–545 Ma (Fig. 2) (e.g. Goodge et al. Reference Goodge, Fanning, Norman and Bennett2012, Paulsen et al. Reference Paulsen, Encarnación, Grunow, Valencia, Pecha, Layer and Rasoazanamparany2013). The other Cambrian–Neoproterozoic rocks in the region (LaGorce and Wyatt formations) are limited to outcrops in the upper reaches of Scott Glacier (Stump et al. Reference Stump, Gehrels, Talarico and Carosi2007). Following the Ross orogeny, exhumation and erosion of the granitic and metamorphic basement of East Antarctica produced the Kukri Peneplain on which the Beacon Supergroup clastic sediments were deposited and intruded by the Ferrar dolerite at c. 180 Ma. In the southern TAM, along the Shackleton Glacier, Elliott & Fanning (Reference Elliot and Fanning2008) describe U-Pb zircon ages in the Buckley and Fremouw formations that shift from almost exclusively Permian–Early Triassic (245–260 Ma) to increasing numbers Ross/Pan-African grains (480–600 Ma; Fig. 2). Ross/Pan-African U-Pb zircon ages are also common in Eocene sandstones inferred to occur in sedimentary basins along the TAM front (e.g. Paulsen et al. Reference Paulsen, Encarnación, Valencia, Roti and Rasoazanamparany2011). An additional potential source of zircons to the upper reaches of Whillans Ice Stream (WIS) is from the Whitmore Mountains (Fig. 1). Flowerdew et al. (Reference Flowerdew, Millar, Curtis, Vaughan, Horstwood, Whitehouse and Fanning2007) report U-Pb detrital zircon ages from sedimentary rocks there with a dominant population 500–550 Ma.

Little is known about the composition, age and extent of rocks inland of the southern TAM, which are buried by the EAIS. Previous work has shown that many nunatak moraines at the head of East Antarctic outlet glaciers in this region contain subglacially-derived sediments, providing a window into the unexposed bedrock that lies beneath the EAIS (e.g. Palmer et al. Reference Palmer, Licht and Swope2012). In contrast, till samples collected from lateral moraines along the valley sides are dominated by input from adjacent wall rock (Palmer et al. Reference Palmer, Licht and Swope2012). U-Pb dating of detrital zircons from nunatak moraines has been completed along the TAM (Schilling Reference Schilling2010, Palmer et al. Reference Palmer, Licht and Swope2012, Welke Reference Welke2013) and provide U-Pb age constraints that represent an integration of geochronological information from East Antarctic outlet glacier catchment areas. In summary, the U-Pb zircon ages from till and bedrock exposures provide the context for understanding the origin of grains found beneath the West Antarctic ice streams and identifying distinctive populations that can be used to trace ice emanating from different parts of the continent.

Materials and methods

Till samples were collected from East and West Antarctic sites in the Ross embayment in order to define the distinguishing characteristics of each source area for comparison with LGM-age Ross Sea tills. Nine samples, comprising 2–5 cm thick intervals, were taken from sediment cores collected beneath WIS, KIS and BIS (Fig. 1, Table I) during the 1992–99 field seasons by researchers at the California Institute of Technology (Kamb & Engelhardt). East Antarctic till samples, collected by Indiana University-Purdue University Indianapolis researchers during field seasons from 2005–11, were selected from moraines found at the base of nunataks near the head of each major outlet glacier, as well as along the length of several of these same glaciers (Fig. 1, Table I). All East Antarctic till collection sites were modern ice-cored moraines, with till thickness ranging from<2 cm to>40 cm. At each site, material was collected 1–3 cm beneath the surface to minimize the effects of wind deflation. Till samples from seven Ross Sea cores collected in sea floor troughs along a transect near the Ross Ice Shelf front (Fig. 1) were obtained from the Antarctic Research Facility at Florida State University. Each of these sample integrated material over a 2–5 cm interval.

Table I Site and sample information.

NA=not applicable.

ˆ Most U-Pb ages previously published in Licht & Palmer (Reference Licht and Palmer2013).

* Part of Beacon Supergroup.

Till samples were sieved to isolate the 63–150 µm fraction and sent to the University of Arizona LaserChron Center for zircon separation using a Frantz magnetic separator combined with heavy liquids following standard methods. Both the unknown zircons and zircons standards (SL=564±4 Ma and R33=419.3±0.4 Ma; Gehrels et al. Reference Gehrels, Valencia and Ruiz2008) were mounted in the middle of 1-inch diameter epoxy pucks and polished to expose the interior of the grains.

The U-Pb analysis on zircon crystals was conducted using a laser ablation multicollector inductively coupled plasma mass spectrometry (LA-MC-ICPMS) (Gehrels et al. Reference Gehrels, Valencia and Ruiz2008). Data were collected over several years from the same lab; initial was work done on a GVI isoprobe, which was upgraded to a Nu HR ICPMS with a photon machines analyte G2 excimer laser. In all cases, a 30 μm diameter pit was ablated into each zircon with the laser. The ablated material was carried by He into the ICPMS where U, Th and Pb isotopes were measured simultaneously. Each measurement was made in static mode for 238U, 232Th, 208Pb, 206Pb, and a discrete dynode ion counter for 204Pb and 202Hg. Each analysis involved one 15 second integration for backgrounds, fifteen 1 second integrations with the laser firing continuously, followed by a 30 second delay to prepare for the next sample. Errors in determining U and P isotopic ratios result in a measurement error of 1–2% (2σ) (Gehrels et al. Reference Gehrels, Valencia and Ruiz2008). Common Pb correction was made using Hg-corrected 204Pb, assuming an initial Pb composition from Stacey & Kramers (Reference Stacey and Kramers1975). Isotopic data collected from the LA-MC-ICPMS was reduced using an Excel macro (‘Agecalc’). The data were filtered for discordance using 30% cut-off in order to retain more Archean ages. The 206Pb/238U age was selected for<1000 Ma zircons, and 206Pb/207Pb age for>1000 Ma grains.

Results

West Antarctica

A total of 630 detrital zircons were analysed from WIS, KIS and BIS (Fig. 3 and Supplemental data found at http://dx.doi.org/10.1017/S0954102014000315). Multiple samples were analysed from each ice stream and combined to produce a single age distribution and provide an integrated dataset representing the till from each site. With only one exception from KIS where one small sample lacked an age of c. 100 Ma, U-Pb age distributions from samples within each ice stream were statistically indistinguishable from each other using the Kolmogorov-Smirnoff test (Schilling Reference Schilling2010). Grain yields from some samples were very low because of the small sample sizes; additional samples and analyses would be required to robustly assess time-transgressive changes in zircon age populations.

Fig. 3 Histogram and cumulative frequency (black line) of detrital zircons younger than 600 Ma from West Antarctic ice stream tills. Inset probability diagram shows age distributions to 1400 Ma and the y-axis shows relative probability. Shaded regions highlight ages of common detrital zircon populations in rocks from the region. a=constraints from Edward VII Peninsula Granites 95–100 Ma (Weaver et al. Reference Weaver, Adams, Pankhurst and Gibson1992), Ford Ranges 102–119 Ma (Korhonen et al. Reference Korhonen, Saito, Brown, Siddoway and Day2010, Siddoway Reference Siddoway2008), and Ruppert and Hobbs coasts Mount Prince Granite c. 110–100 Ma (Mukasa & Dalziel Reference Mukasa and Dalziel2000), b=Ford Granodiorite and related rocks, c=Ross orogeny and Swanson Formation detrital zircons 500–600 Ma.

The age distributions for WIS and KIS are similar, with a dominant single Cambrian peak, a smaller but significant Mesoproterozoic population and few older grains (Fig. 3 insets). The Cambrian peak overlaps with the timing of the Ross orogeny and this age population from both sites extends into the late Neoproterozoic. In contrast, BIS till shows a strongly bimodal distribution across this time interval, with peaks at 485 and 550 Ma (Fig. 3 inset). The till from this site also has a larger number of Mesoproterozoic and older grains compared to the other two sites.

At all sites, the Devonian- to Jurassic-age zircons are much lower in abundance than older grains and show the number of ages in this range increasing toward Marie Byrd Land. Some peaks in the probability curves represent only one or two grains (Fig. 3); probability peaks are typically considered geologically meaningful when three or more concordant ages overlap (Gehrels et al. Reference Gehrels, Valencia and Ruiz2008). Based on this criterion, WIS till lacks any significant peaks in this range, KIS till has one at 170–190 Ma, and BIS till has age clusters of interest at 330–350 Ma and 200–210 Ma. Significantly, only KIS and BIS contain a mid-Cretaceous peak c. 100–110 Ma (Fig. 3).

Ross Sea

A total of 501 detrital zircons were analysed from seven cores in the Ross Sea (Fig. 4 and Supplemental data found at http://dx.doi.org/10.1017/S0954102014000315). All of the Ross Sea samples, except 94-39, are dominated by Cambrian–late Neoproterozoic U-Pb ages. The proportion of grains in the younger part of this range, 480–550 Ma, increases eastward toward West Antarctica. Core 99-17 has a bimodal distribution across this interval, similar to the peaks in BIS tills. Generally, the cores show east–west spatial variability in the content of Mesozoic grains. Cores collected east of 180° longitude have a higher proportion of Mesozoic grains and also contain a c. 100–110 Ma age population, consistent with the ages from KIS and BIS. This peak is absent in the cores west of the 180° longitude. Several of the probability peaks in the Mesozoic, including all peaks in core 32-20, are not considered geologically meaningful based on these data because they are the product of fewer than three concordant ages.

Fig. 4 Distribution of U-Pb zircon ages from West Antarctica, the Ross Sea and East Antarctic outlet glaciers shown by histograms of the number of ages and probability density (black curve). Note the presence of U-Pb ages 100–110 Ma is limited to Ross Sea core sites east of 180°. Number of grains refers only to ages<800 Ma shown, not the total number measured; see Supplemental data table for complete list of ages. The histogram y-axes values are necessarily variable.

East Antarctica

A total of 2796 detrital zircons were analysed from 13 East Antarctic sample sites and the 1795 ages that are 800 Ma and younger are shown in Fig. 4. For the purposes of this study, the East Antarctic tills have been amalgamated into two groups, sites from nunatak moraines at the head of outlet glaciers and downstream sites from the valley sides to the mouth. Ten sites from Byrd Glacier to Reedy Glacier (Fig. 1) represent the nunatak moraines and they show three main populations. Around 30% of the grains are Mesoproterozoic and older, 29% of ages are 550–610 Ma, and 5% are 240–270 Ma (Fig. 4). In contrast, three downstream sites from Byrd and Scott glaciers have a single dominant peak 530–540 Ma, with a small proportion of grains 550–610 Ma.

Discussion

The response of the WAIS to climatic and oceanographic forcings is of primary interest to the scientific community and identifying a distinctive tracer that can be used to constrain ice flow in both proximal and distal glacial sediments is key to placing limits on past fluctuations of the WAIS. Subglacial till samples were available for three of the Siple Coast ice streams and these allow us to directly fingerprint the ice streams and understand better the origin of West Antarctic basin fill. Whereas traditional sand petrological studies have been successfully used to link onshore and offshore tills (Licht et al. Reference Licht, Lederer and Swope2005, Licht & Palmer Reference Licht and Palmer2013), the methodology can be more difficult in distal glacial marine deposits where the number of sand grains is too small to develop reliable statistical sampling, and common minerals such as quartz are not easily traced back to their source. Detrital minerals, such as zircon and amphibole, can be more useful in these cases by providing both composition and geochronological data to more easily tie grains to their region of origin (e.g. Pierce et al. Reference Pierce, Williams, van de Flierdt, Hemming, Goldstein and Brachfeld2011, Licht & Palmer Reference Licht and Palmer2013). The focus here is on the geographical variability in U-Pb detrital zircon ages in WAIS tills that can be applied to ice sheet reconstructions over a variety of temporal and spatial scales, with emphasis on the LGM.

U-Pb ages in West Antarctic tills and their origin

The U-Pb ages from WIS till are predominantly late Neoproterozoic–Cambrian and over 50% of grains have ages between 500–600 Ma (Fig. 3). Peaks in the probability plot at 505 Ma and 535 Ma, commonly called the Ross-age peak, are consistent with the age of the Granite Harbour Intrusives formed during the Ross orogeny. The Granite Harbour Intrusives are mapped along much of the length of the TAM front and outcrop in areas closest to the catchments of the Whillans/Mercer ice streams, including the Ohio Range to Reedy Glacier (Fig. 1) (Mirsky Reference Mirsky1969). As noted earlier, U-Pb zircon ages from bedrock samples of the Granite Harbour Intrusives are typically 485–545 Ma and moraines along the TAM outlet glacier valleys flanked by the Granite Harbour Intrusives produce U-Pb zircon ages that are predominantly 500–550 Ma (‘downstream moraines’ in Fig. 4) (Schilling Reference Schilling2010, Licht & Palmer Reference Licht and Palmer2013). The moraine closest to WIS for which there are detrital zircon U-Pb ages is at the base of the Scott Glacier, where 64% of grains have U-Pb ages 500–550 Ma, with the highest probability peak at 530 Ma (Schilling Reference Schilling2010). From these observations, combined with information about current ice flow paths, it is probable that the bulk of detrital zircons, and by association the remainder of sediment beneath the WIS, has accumulated over time from erosion of coastal outcrops of the TAM and/or basement highs in West Antarctica.

The presence of grains>550 Ma in WIS till suggests that this part of the West Antarctic basin also contains some material derived from sources other than the Granite Harbour Intrusives. Such ages are associated with an early phase of the Ross orogeny, the Pan-African orogeny, and the Grenville orogeny (1300–1000 Ma). Zircon ages 500–1200 Ma can be found in siliciclastic rocks from the Beacon Supergroup (Elliott & Fanning Reference Elliot and Fanning2008) which outcrop in the southern TAM, the Swanson Formation, a pre-Devonian accretionary complex on Edward VII Peninsula in Marie Byrd Land (Pankhurst et al. Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998) and Eocene sandstone erratics found near McMurdo Sound (e.g. Paulsen et al. Reference Paulsen, Encarnación, Valencia, Roti and Rasoazanamparany2011). Considering the distance of the known Swanson Formation outcrops from the WIS and the subglacial topography, this seems a less likely source than the TAM for sediments found beneath WIS. It is highly probable that the populations>550 Ma have been recycled and do not represent erosion of primary bedrock sources.

The detrital zircon age distribution from KIS till is similar to that of WIS till, with the highest proportion of grains falling in the Cambrian accompanied by a much smaller fraction of Mesozoic and Proterozoic grains (Fig. 3). The maximum probability peak is at 510 Ma. Similar to WIS, we infer a TAM source for these ‘Ross-age’ grains. Differences from WIS include a higher number of ages Ordovician (488 Ma) and younger. In particular, the relatively large number of grains c. 450–480 Ma is more similar to BIS till than WIS till, and is younger than most known Granite Harbour Intrusives. The youngest U-Pb age reported from an igneous intrusion in the southern TAM is 484.7±8.4 Ma; samples were from the coastal Fallone Nunataks between the Reedy and Scott glaciers (Paulsen et al. Reference Paulsen, Encarnación, Grunow, Valencia, Pecha, Layer and Rasoazanamparany2013). If such ages were common along coastal outcrops, then WIS tills would be expected to contain a higher fraction of this population than KIS tills. However, the fraction of grains 450–480 Ma in tills increases toward Marie Byrd Land, not toward the TAM. The outcrop source of these grains is not known but may be related to a late plutonic phase of the Ross orogeny seaward of the TAM and currently located within the West Antarctic basin.

The KIS till contains a U-Pb age peak at c. 100–110 Ma. The number of grains is small, but such young ages are not known from East Antarctic outcrops and have not been found in thousands of analyses from East Antarctic tills (Schilling Reference Schilling2010, Licht & Palmer Reference Licht and Palmer2013, Welke Reference Welke2013). Several sources from Marie Byrd Land are consistent with this age and could have contributed grains into the West Antarctic basin prior to glaciation. Leucogranites from the Fosdick Mountains in the Ford Ranges have U-Pb ages 100–120 Ma (Siddoway Reference Siddoway2008, Korhonen et al. Reference Korhonen, Saito, Brown, Siddoway and Day2010), and K-Ar age of biotites within the nearby Edward VII granites yield a similar range (95–100 Ma) (Weaver et al. Reference Weaver, Adams, Pankhurst and Gibson1992). Granitoids and felsic and intermediate dike swarms with U-Pb ages of 101–110 Ma have also been reported along the Ruppert and Hobbs coasts of western Marie Byrd Land (Mukasa & Dalziel Reference Mukasa and Dalziel2000). Additional analyses would be required to further refine the source of these grains, but the source must be limited to Marie Byrd Land.

The U-Pb age distribution of BIS has several distinctive features, including a strong bimodal distribution of Cambrian–Ordovician grains (Fig. 3) rather than the more typical single Ross-age peak. Furthermore, BIS has a higher proportion of grains>600 Ma as indicated by the cumulative frequency curve in Fig. 3. Almost 50% of grains are>600 Ma, with the majority of these having ages 1000–1100 Ma (Fig. 3 inset). A small number of ages are scattered across the Proterozoic and even extend back to the Archean (Schilling Reference Schilling2010). The BIS till contains the highest proportion of grains younger than 400 Ma, with at least three significant discrete populations.

In BIS till, the typical Ross-age peak is replaced by two U-Pb age populations centred at 485 Ma and 550 Ma. As noted earlier, the source of zircons 450–475 Ma is unknown, but their absence from the TAM where the geology is better exposed and the number of grains in this age range increases toward Marie Byrd Land, thus zircons 450–475 Ma are considered to be a signal of ice originating in West Antarctica, north of c. 83°S. Further studies beyond the scope of this project would be required to determine the specific geological origin of these grains.

Zircon ages 540–590 Ma and 1000–1100 Ma overlap with ages known from outcrops in the TAM (Fig. 2), as well as till from East Antarctic nunataks. However, the relatively high numbers in BIS till but lower proportion in KIS till suggest a different origin. Because the BIS catchment is completely within the West Antarctic basin and lies closer to Marie Byrd Land than the TAM, these grains probably originated from the Swanson Formation of Marie Byrd Land from which Pankhurst et al. (Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998) reported grains with similar ages. The material may have been shed south-westward into the West Antarctic basin from the Marie Byrd Land dome during a period of mid-Cretaceous erosion (LeMasurier & Landis Reference LeMasurier and Landis1996) with subsequent incorporation into sub-ice stream tills. Alternatively, they could have been derived from unknown subglacial outcrops within the basin. These data highlight the challenge of identifying the source of ubiquitous U-Pb ages without other discriminating information.

As noted above, BIS tills show three clusters of zircon ages<400 Ma. The oldest of these is c. 330–370 Ma, which is consistent with derivation from the Ford Granodiorite and related rocks from Edward VII Peninsula, the Fosdick Mountains and/or the Ruppert and Hobbs coasts (Fig. 2) (Pankhurst et al. Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998, Mukasa & Dalziel Reference Mukasa and Dalziel2000, Siddoway & Fanning Reference Siddoway and Fanning2009). The second age cluster spans the Triassic–Jurassic boundary and has fewer grains. Similar ages are seen in KIS till, but across a wider range. No clear source of these grains has been identified; a few grains with slightly older ages (220–250 Ma) have been identified from the Cretaceous Alexandra Mountains metamorphic complex, which outcrops on Edward VII Peninsula (Pankhurst et al. Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998), and in sandstones of the Section Peak Formation in north Victoria Land (Elsner et al. Reference Elsner, Schöner, Gerdes and Gaupp2013). The broad distribution of ages makes this a less reliable West Antarctic tracer than others discussed. The youngest and sharpest peak is 100–110 Ma, which is similar in age to, but more abundant than in, KIS tills. As discussed above, there are several possible Marie Byrd Land sources for these zircons and it is considered to be a key fingerprint of the WAIS.

Summary of West Antarctic U-Pb tracers

The distinctive U-Pb age populations among detrital zircons from BIS and KIS tills provide an important tracer for the northern two-thirds of the WAIS catchment in the Ross embayment, including ice adjacent to the catchment of Thwaites Glacier. Overall, the most distinctive signature of West Antarctic-derived ice is the 100–110 Ma U-Pb age population. This tracer applies to ice emanating from Marie Byrd Land to KIS. These findings are consistent with Ar-Ar ages of ice-rafted hornblende grains found in surface sediments offshore West Antarctica (Roy et al. Reference Roy, van de Flierdt, Hemming and Goldstein2007). In contrast, the absence of 100–110 Ma grains from WIS till, combined with nearly complete overlap with ages from East Antarctic sources means that U-Pb ages cannot be used to uniquely trace the WIS flow path. Detrital zircons associated with the Ross/Pan-African orogeny (480–625 Ma) are widespread in sediment and rocks from the Ross embayment East and West Antarctic tills, Permian Beacon Supergroup sandstones, the Swanson Formation and in offshore sediments (Fig. 2) (Pankhurst et al. Reference Pankhurst, Weaver, Bradshaw, Storey and Ireland1998, Elliott & Fanning Reference Elliot and Fanning2008, Schilling Reference Schilling2010, Palmer et al. Reference Palmer, Licht and Swope2012, Licht & Palmer Reference Licht and Palmer2013), and thus must be interpreted with caution. The results from this study indicate that zircon grains 450–475 Ma are supplied by West Antarctic ice north of c. 83°S, as their abundance increases with proximity to Marie Byrd Land and the TAM lack zircons of these ages. Interestingly, the West Antarctic tills lack a cluster of ages 240–270 Ma reported by Elliott & Fanning (Reference Elliot and Fanning2008) to be abundant in Permo–Triassic sandstones of the Buckley and Fremouw formations (Beacon Supergroup) and interpreted to have originated from arc-volcanism in West Antarctica.

West Antarctica/Ross Sea till comparison

The U-Pb ages from tills deposited on the Ross Sea continental shelf during the LGM were analysed to compare with West and East Antarctic tills in order to determine whether distinctive age populations were identifiable in downstream subglacial deposits. Histograms and probability plots were created for ages<800 Ma, showing zircon age distributions from each ice stream, an east–west transect of Ross Sea cores, as well as East Antarctic tills collected along the TAM. Samples from the TAM were combined into two groups: i) till from moraines along valley sides to the mouth (downstream moraines), and ii) nunatak moraines from the head of major East Antarctic outlets (Fig. 4). Here the focus is on the presence or absence of unique grain populations to trace flow paths rather than relying on statistical tests of population similarity. This approach highlights age populations that may be made up of a relatively small number of ages, but having critical provenance information.

The two characteristic features of BIS till, a narrow age peak at 100–110 Ma and the double Ross-age peak, are present in core 99-17, the easternmost Ross Sea sample analysed (Fig. 4). Core 94-63, located one trough westward, also shows a 100–110 Ma peak, but lacks the characteristic bimodal peaks at 485 Ma and 550 Ma. The signature of KIS till is a single Ross-age population, peaking at 510 Ma, and a small number of grains 100–110 Ma. Core 94-63 shows both these populations (Fig. 4), though the core has a higher proportion of grains 100–110 Ma. Relative to KIS, the till in 94-63 has a higher fraction of grains 460–480 Ma, more similar to ages found in BIS till, suggesting some input of ice from areas now within the BIS catchment. Core 94-39 has the highest proportion of grains 100–110 Ma and a muted Ross-age peak, unlike any other West or East Antarctic tills analysed. Unfortunately, the zircon yields in this core were quite small (n=30) reducing the likelihood that the age distribution fully represents the populations in the till. However, the presence of the 100–110 Ma population is interpreted as a clear signal that West Antarctic-derived ice flowed over this site during the LGM. We speculate that mid-Cretaceous bedrock provinces extend offshore of the Edward VII Peninsula into the Ross Sea and outcrop on subglacial high points, such as Roosevelt Island or Siple Dome, providing a local source of zircons with this distinctive age. Geophysical surveys of Siple Dome indicate that the associated subglacial topographical high is essentially devoid of a till cover (Gades et al. Reference Gades, Raymond, Conway and Jacobel2000), allowing subglacial erosion to readily access this bedrock.

West of 180° longitude, the 100–110 Ma zircons are absent from Ross Sea tills and the probability of finding grains 550–610 Ma increases (Fig. 4). Almost 2800 zircon grains analysed from moraines distributed along the TAM are completely devoid of 100–110 Ma grains and tills from nunatak moraines are overwhelmingly 550–610 Ma grains. This combination indicates that cores in the western half of the Ross Sea contain sediment derived from East Antarctica. As noted above, the U-Pb ages in WIS till cannot be distinguished from ‘downstream’ East Antarctic tills eroded from outcrops of the TAM. Core 32-21 has the most similar age distribution to WIS till, with a Ross-age peak centred at 520 Ma. While most of the Ross Sea cores have a very small number of concordant ages that span the Cretaceous and Jurassic (Fig. 4), they cannot be considered geologically significant because they lack clusters of three or more overlapping ages and also lack a potential outcrop source.

The complex process of till accumulation and lack of high-resolution chronology within the Ross Sea tills means that it is not possible to determine whether all the LGM till represents the same snapshot in time even though all samples were collected in the upper 1.5 m of sediment. Previous analysis of seismic facies by Shipp et al. (Reference Shipp, Anderson and Domack1999) shows that the LGM till package in the inner Ross Sea is 0–5 m thick. Unfortunately, the strength of the till results in incomplete recovery of the full thickness, thus preventing measurement of provenance changes throughout the entire section. Where multiple samples from a single core (Ross Sea or ice stream) have been analysed, substantial variability with depth is not observed. However, the small core diameter means that the number of grains available for analysis is often less than optimal for robust statistical comparison. From this dataset, a time-transgressive analysis of possible flow direction changes within the LGM cannot be created.

Palaeoflow reconstruction

Model reconstructions of ice filling the Ross embayment during the LGM have shown a range of inputs from West and East Antarctica, with variable configurations of palaeo ice streams (e.g. Pollard & DeConto Reference Pollard and DeConto2009, Golledge et al. Reference Golledge, Levy, McKay, Fogwill, White, Graham, Smith, Hillenbrand, Licht, Denton, Ackert, Maas and Hall2013). The U-Pb ages reported here provide field data constraints on flow that can be used to place limits on modelling efforts and serve as an example of how such datasets can be useful in regions of convergent flow even when the subglacial bedrock geology is not well known. Sub-ice stream U-Pb fingerprints show a high level of similarity to offshore tills allowing refinement of flowlines described in Licht et al. (Reference Licht, Lederer and Swope2005) and Farmer et al. (Reference Farmer, Licht, Swope and Andrews2006). The addition of a large number of new samples compared to previous studies allows us to fill in what were inferred flowlines. The new flowline reconstruction, built on this more robust dataset, is shown in Fig. 5. Ice flowlines are based on both the overall age population distribution and the presence of geologically significant peaks, such as 100–110 Ma. These particular ages show that the boundary between the modern KIS and WIS was between troughs 3 and 4 during the LGM. This is largely consistent with previous reconstructions based on sand petrography and εNd. That trough 3 was an area of convergent flow and high velocity ice is supported by both field observations of strong sea floor lineations (Shipp et al. Reference Shipp, Anderson and Domack1999) and numerical model results from Golledge et al. (Reference Golledge, Levy, McKay, Fogwill, White, Graham, Smith, Hillenbrand, Licht, Denton, Ackert, Maas and Hall2013).

Fig. 5 Late Quaternary ice flow reconstruction for the Ross embayment. Orange dots highlight sample locations with U-Pb ages 100–110 Ma. Sea floor troughs are numbered following the convention in Mosola & Anderson (Reference Mosola and Anderson2006). RI=Roosevelt Island, SD=Siple Dome, other abbreviations are the same as in Fig. 1.

The closest model-data fit comes from a time-transgressive simulation described by Golledge et al. (Reference Golledge, Levy, McKay, Fogwill, White, Graham, Smith, Hillenbrand, Licht, Denton, Ackert, Maas and Hall2013, fig. 13B) where flow paths during ice advance, highlighted by a time-dependent particle tracking method, show a better match than ice flow under steady-state conditions during the LGM. Their model simulations suggest that till mobilization is most prevalent during transient glacial states, especially during initial ice advance. Field and modelling based studies provide support for the idea that grounded ice did not reside in the Ross Sea long enough during the LGM to achieve a steady-state (e.g. Licht & Andrews Reference Licht and Andrews2002). Compared to the results of this study, the models of the ice sheet maximum in Denton & Hughes (Reference Denton and Hughes2002) and Golledge et al. (Reference Golledge, Levy, McKay, Fogwill, White, Graham, Smith, Hillenbrand, Licht, Denton, Ackert, Maas and Hall2013) tend to overpredict the input of ice derived from the southern TAM resulting in some mismatch with data in the area of trough 4; the rest of the flowlines are very similar. Although it is not possible to determine empirically whether the provenance information reported here relates to the ice flow configuration during advance, maximum or retreat, future studies and newer analytical techniques may be able to help resolve the temporal changes in flow path differences predicted by model simulations.

Conclusions

Detrital zircons contained within glacial till can be a valuable tracer of past ice flow, even in regions around Antarctica where the bedrock geology is not well known. In the Ross embayment, distinctive populations that show a limited spatial extent in interior regions of the continent are found in offshore glacial deposits. In particular, U-Pb zircon ages of 100–110 Ma, which are derived from rocks outcropping in Marie Byrd Land, occur in BIS and KIS tills and in LGM tills from the eastern Ross Sea. Such grains are absent from WIS tills, which do not have a U-Pb detrital zircon fingerprint that allows them to be distinguished from tills collected from the TAM. A comparison between zircon ages from East and West Antarctic source areas and LGM offshore tills allows us to trace ice originating in West Antarctica, north of c. 83°S, to the area east of 180° longitude.

Acknowledgements

The work was supported by grants to Licht by NSF-OPP (0440885, 0944578, 1043572), to the University of Arizona LaserChron Center (NSF-EAR 1032156), and by IUPUI’s RSFG. The following assisted with sample collection or provided material from independent sample collections: H. Engelhardt, N. Bader, A. Barth, P. Braddock, D. Brecke, J. Goodge, E. Hiatt, K. Kramer, E. Palmer, and pilots of Ken Borek Air, Ltd. We appreciate the field support provided by US Antarctic Program and Raytheon Polar Services. Helpful comments and suggestions were provided by M. Flowerdew and two anonymous reviewers.

Supplemental material

A supplemental table will be found at http://dx.doi.org/10.1017/S0954102014000315.

References

Anderson, J.B., Conway, H., Bart, P.J., Witus, A.E., Greenwood, S.L., McKay, R.M., Hall, B.L., Ackert, R.P., Licht, K., Jakobsson, M. & Stone, J.O. In press. Ross Sea paleo-ice sheet drainage and deglacial history during and since the LGM. Quaternary Science Reviews. 10.1016/j.quascirev.2013.08.020.Google Scholar
Andrews, J.T., Domack, E.W., Cunningham, W.L., Leventer, A., Licht, K.J., Jull, A.J.T., DeMaster, D.J. & Jennings, A.E. 1999. Problems and possible solutions concerning radiocarbon dating of surface marine sediments, Ross Sea, Antarctica. Quaternary Research, 52, 206216.Google Scholar
Bromwich, D.H., Nicolas, J.P., Monaghan, A.J., Lazzara, M.A., Keller, L.M., Weidner, G.A. & Wilson, A.B. 2013. Central West Antarctica among the most rapidly warming regions on Earth. Nature Geoscience, 6, 139145.Google Scholar
Christoffersen, P., Tulaczyk, S. & Behar, A. 2010. Basal ice sequences in Antarctic ice stream: exposure of past hydrologic conditions and a principal mode of sediment transfer. Journal of Geophysical Research - Earth Surface, 115, 10.1029/2009JF001430.Google Scholar
Denton, G.H. & Hughes, T.J. 2002. Reconstructing the Antarctic ice sheet at the Last Glacial Maximum. Quaternary Science Reviews, 21, 193202.Google Scholar
Elliot, D.H. & Fanning, C.M. 2008. Detrital zircons from upper Permian and lower Triassic Victoria Group sandstones, Shackleton Glacier region, Antarctica: evidence for multiple sources along the Gondwana plate margin. Gondwana Research, 13, 259274.Google Scholar
Elsner, M., Schöner, R., Gerdes, A. & Gaupp, R. 2013. Reconstruction of the early Mesozoic plate margin of Gondwana by U-Pb ages of detrital zircons from northern Victoria Land, Antarctica. In Harley, S.L., Fitzsimons, I.C.W. & Zhao, Y., eds. Antarctica and supercontinent evolution. London: Geological Society Special Publications, 237 pp.Google Scholar
Farmer, G.L., Licht, K., Swope, R.J. & Andrews, J. 2006. Isotopic constraints on the provenance of fine-grained sediment in LGM tills from the Ross embayment, Antarctica. Earth and Planetary Science Letters, 249, 90107.Google Scholar
Flowerdew, M.J., Millar, I.L., Curtis, M.L., Vaughan, A.P.M., Horstwood, M.S.A., Whitehouse, M.J. & Fanning, C.M. 2007. Combined U-Pb geochronology and Hf isotope geochemistry of detrital zircons from early Paleozoic sedimentary rocks, Ellsworth-Whitmore Mountains block, Antarctica. Geological Society of America Bulletin, 119, 275288.Google Scholar
Flowerdew, M.J., Tyrrell, S. & Peck, V.L. 2013. Inferring sites of subglacial erosion using the Pb isotopic composition of ice-rafted feldspar: examples from the Weddell Sea, Antarctica. Geology, 41, 147150.CrossRefGoogle Scholar
Gades, A.M., Raymond, C.F., Conway, H. & Jacobel, R.W. 2000. Bed properties of Siple Dome and adjacent ice streams, West Antarctica, inferred from radio-echo sounding measurements. Journal of Glaciology, 46, 8894.Google Scholar
Gehrels, G.E., Valencia, V.A. & Ruiz, J. 2008. Enhanced precision, accuracy, efficiency, and spatial resolution of U-Pb ages by laser ablation-multicollector-inductively coupled plasma-mass spectrometry. Geochemistry, Geophysics, Geosystems, 9, 10.1029/2007GC001805.Google Scholar
Golledge, N.R., Levy, R.H., McKay, R.M., Fogwill, C.J., White, D.A., Graham, A.G.C., Smith, J.A., Hillenbrand, C.D., Licht, K.J., Denton, G.H., Ackert, R.P. Jr, Maas, S.M. & Hall, B.L. 2013. Glaciology and geological signature of the last glacial maximum Antarctic ice sheet. Quaternary Science Reviews, 78, 225247.CrossRefGoogle Scholar
Goodge, J.W., Fanning, C.M., Norman, M.D. & Bennett, V.C. 2012. Temporal, isotopic and spatial relations of early Paleozoic Gondwana-margin arc magmatism, central Transantarctic Mountains, Antarctica. Journal of Petrology, 53, 20272065.Google Scholar
Joughin, I. & Alley, R.B. 2011. Stability of the West Antarctic Ice Sheet in a warming world. Nature Geoscience, 4, 506513.Google Scholar
Korhonen, F.J., Saito, S., Brown, M., Siddoway, C.S. & Day, J.M.D. 2010. Multiple generations of granite in the Fosdick Mountains, Marie Byrd Land, West Antarctica: implications for polyphase intracrustal differentiation in a continental margin setting. Journal of Petrology, 51, 627670.Google Scholar
LeMasurier, W.E. & Landis, C.A. 1996. Mantle-plume activity recorded by low-relief erosion surfaces in West Antarctica and New Zealand. Geological Society of America Bulletin, 108, 14501466.Google Scholar
Licht, K.J. & Andrews, J.T. 2002. The 14C record of late Pleistocene ice advance and retreat in the central Ross Sea, Antarctica. Arctic, Antarctic and Alpine Research, 34, 324333.Google Scholar
Licht, K.J. & Palmer, E.F. 2013. Erosion and transport by Byrd Glacier, Antarctica during the last glacial maximum. Quaternary Science Reviews, 62, 3248.Google Scholar
Licht, K.J., Lederer, J.R. & Swope, R.J. 2005. Provenance of LGM glacial till (sand fraction) across the Ross embayment, Antarctica. Quaternary Science Reviews, 24, 14991520.Google Scholar
Mirsky, A. 1969. Geology of the Ohio Range–Liv Glacier area. In Bushnell, V.C. & Craddock, C., eds. Antarctic map folio series, folio 12 – geology. XV (17, Ohio Range to Liv Glacier), 1:1 000 000. New York: American Geographical Society.Google Scholar
Mosola, A.B. & Anderson, J.B. 2006. Expansion and rapid retreat of the West Antarctic Ice Sheet in eastern Ross Sea: possible consequence of over-extended ice streams? Quaternary Science Reviews, 25, 21772196.Google Scholar
Mukasa, S.B. & Dalziel, I.W.D. 2000. Marie Byrd Land, West Antarctica: evolution of Gondwana’s Pacific margin constrained by zircon U-Pb geochronology and feldspar common-Pb isotopic compositions. Geological Society of America Bulletin, 112, 611627.Google Scholar
Naish, T., Powell, R. & Levy, R. & 55 others. 2009. Obliquity-paced Pliocene West Antarctic Ice Sheet oscillations. Nature, 458, 322328.Google Scholar
O’Leary, M.J., Hearty, P.J., Thompson, W.G., Raymo, M.E., Mitrovica, J.X. & Webster, J.M. 2013. Ice sheet collapse following a prolonged period of stable sea level during the last interglacial. Nature Geoscience, 6, 796800.Google Scholar
Palmer, E.F., Licht, K.J. & Swope, R.J. 2012. Nunatak moraines as a repository of what lies beneath the East Antarctic Ice Sheet. Geological Society of America Special Paper, 487, 97104.Google Scholar
Pankhurst, R.J., Weaver, S.D., Bradshaw, J.D., Storey, B.C. & Ireland, T.R. 1998. Geochronology and geochemistry of pre-Jurassic superterranes in Marie Byrd Land, Antarctica. Journal of Geophysical Research - Solid Earth, 103, 25292547.Google Scholar
Paulsen, T., Encarnación, J., Valencia, V.A., Roti, J.M.R. & Rasoazanamparany, C. 2011. Detrital U-Pb zircon analysis of an Eocene McMurdo Erratic sandstone, McMurdo Sound, Antarctica. New Zealand Journal of Geology and Geophysics, 54, 353360.Google Scholar
Paulsen, T.S., Encarnación, J., Grunow, A.M., Valencia, V.A., Pecha, M., Layer, P.W. & Rasoazanamparany, C. 2013. Age and significance of ‘outboard’ high-grade metamorphics and intrusives of the Ross orogen, Antarctica. Gondwana Research, 24, 349358.Google Scholar
Peters, L.E., Anandakrishnan, S., Alley, R.B., Winberry, J.P., Voight, D.E., Smith, A.M. & Morse, D.L. 2006. Subglacial sediments as control on the onset and location of two Siple Coast ice streams, West Antarctica. Journal of Geophysical Research - Solid Earth, 111, 10.1029/2005JB003766.Google Scholar
Pierce, E.L., Williams, T., van de Flierdt, T., Hemming, S.R., Goldstein, S.L. & Brachfeld, S.A. 2011. Characterizing the sediment provenance of East Antarctica’s weak underbelly: the Aurora and Wilkes sub-glacial basins. Paleoceanography, 26, 10.1029/2011PA002127.Google Scholar
Pollard, D. & DeConto, R.M. 2009. Modelling West Antarctic Ice Sheet growth and collapse through the past five million years. Nature, 458, 329332.Google Scholar
Roy, M., van de Flierdt, T., Hemming, S.R. & Goldstein, S.L. 2007. 40Ar/39Ar ages of hornblende grains and bulk Sm/Nd isotopes of circum-Antarctic glacio-marine sediment: implications for sediment provenance in the Southern Ocean. Chemical Geology, 244, 507519.Google Scholar
Schilling, A.J. 2010. Reconstructing past Antarctic ice flow paths in the Ross embayment, Antarctica using sand petrography, particle size and detrital zircon provenance. MSc thesis, Indiana University, 128 pp. [Unpublished].Google Scholar
Shipp, S., Anderson, J. & Domack, E. 1999. Late Pleistocene-Holocene retreat of the West Antarctic Ice Sheet system in the Ross Sea: Part 1: Geophysical results. Geological Society of America Bulletin, 111, 14861516.Google Scholar
Siddoway, C.S. 2008. Tectonics of the West Antarctic rift system: new light on the history and dynamics of distributed intracontinental extension. In Cooper, A., Raymond, C. & the 10th ISAES editorial team, eds. Antarctica: a keystone in a changing world. Washington: The National Academies Press, keynote paper 009.Google Scholar
Siddoway, C.S. & Fanning, C.M. 2009. Paleozoic tectonism on the East Gondwana margin: evidence from SHRIMP U-Pb zircon geochronology of a migmatite-granite complex in West Antarctica. Tectonophysics, 477, 262277.Google Scholar
Stacey, J.S. & Kramers, J.D. 1975. Approximation of terrestrial lead isotope evolution by a 2-stage model. Earth and Planetary Science Letters, 26, 207221.Google Scholar
Stump, E., Gehrels, G., Talarico, F. & Carosi, R. 2007. Constraints from detrital zircon geochronology on the early deformation of the Ross orogen, Transantarctic Mountains, Antarctica. In Cooper, A., Raymond, C. & the 10th ISAES editorial team, eds. Antarctica: a keystone in a changing world. Washington: The National Academies Press, Extended Abstract 166, 1–3.Google Scholar
Tingey, R.J. 1991. The regional geology of Archaean and Proterozoic rocks in Antarctica. In Tingey, R.J., ed. The geology of Antarctica, Oxford monographs on geology and geophysics. Oxford: Clarendon Press, 173.Google Scholar
Weaver, S.D., Adams, C.J., Pankhurst, R.J. & Gibson, I.L. 1992. Granites of Edward VII Peninsula, Marie Byrd Land: anorogenic magmatism related to Antarctic-New Zealand rifting. Transactions of the Royal Society of Edinburgh - Earth Sciences, 83, 281290.Google Scholar
Welke, B.M. 2013. Double dating detrital zircons in till from the Ross embayment, Antarctica. MSc thesis, Indiana University, 115 pp. [Unpublished].Google Scholar
Winberry, J.P. & Anandakrishnan, S. 2004. Crustal structure of the West Antarctic rift system and Marie Byrd Land hotspot. Geology, 32, 977980.Google Scholar
Figure 0

Fig. 1 Relief map of Ross embayment area of study from GeoMapApp. Yellow dots show sample locations. B=Beardmore Glacier, BIS=Bindschadler Ice Stream, By=Byrd Glacier, CRS=central Ross Sea, Ed VII=Edward VII Peninsula, ERS=eastern Ross Sea, FR=Ford Ranges, KIS=Kamb Ice Stream, L=Law Glacier, McIS=MacAyeal Ice Stream, MIS=Mercer Ice Stream, N=Nimrod Glacier, OR=Ohio Range, R=Reedy Glacier, S=Scott Glacier, WIS=Whillans Ice Stream, WM=Whitmore Mountains, WRS=western Ross Sea.

Figure 1

Fig. 2 Diagram shows the relative frequency of Phanerozoic U-Pb zircon ages from dominant bedrock types surrounding the study area. Darker shades of grey indicate a higher frequency of grains relative to the total distribution from that rock type. BCG +=Byrd Coast Granite plus others described in text, ES=Eocene sandstone, FG +=Ford Granodiorite plus others described in text, GHI=Granite Harbour Intrusives, SF=Swanson Formation.

Figure 2

Table I Site and sample information.

Figure 3

Fig. 3 Histogram and cumulative frequency (black line) of detrital zircons younger than 600 Ma from West Antarctic ice stream tills. Inset probability diagram shows age distributions to 1400 Ma and the y-axis shows relative probability. Shaded regions highlight ages of common detrital zircon populations in rocks from the region. a=constraints from Edward VII Peninsula Granites 95–100 Ma (Weaver et al.1992), Ford Ranges 102–119 Ma (Korhonen et al.2010, Siddoway 2008), and Ruppert and Hobbs coasts Mount Prince Granite c. 110–100 Ma (Mukasa & Dalziel 2000), b=Ford Granodiorite and related rocks, c=Ross orogeny and Swanson Formation detrital zircons 500–600 Ma.

Figure 4

Fig. 4 Distribution of U-Pb zircon ages from West Antarctica, the Ross Sea and East Antarctic outlet glaciers shown by histograms of the number of ages and probability density (black curve). Note the presence of U-Pb ages 100–110 Ma is limited to Ross Sea core sites east of 180°. Number of grains refers only to ages<800 Ma shown, not the total number measured; see Supplemental data table for complete list of ages. The histogram y-axes values are necessarily variable.

Figure 5

Fig. 5 Late Quaternary ice flow reconstruction for the Ross embayment. Orange dots highlight sample locations with U-Pb ages 100–110 Ma. Sea floor troughs are numbered following the convention in Mosola & Anderson (2006). RI=Roosevelt Island, SD=Siple Dome, other abbreviations are the same as in Fig. 1.

Supplementary material: File

Licht et al. supplementary material

Supplementary data

Download Licht et al. supplementary material(File)
File 309.8 KB