Origin of tabular massive ground ice in the raised marine-deltaic sediments

The origin of the bodies of massive ice can be inferred by combining various approaches (i.e., cryostratigraphic observations, chemistry, and δD-δ¹⁸O of the ice). At the three sites, and others in the ESL, the massive ice is found stratigraphically below laminated fine-grained marine sediments, and the upper contact between the ice and the overlying marine sediments is conformable and gradational. Marine sediments also occur as thin layers within the upper part of the ice. The internal structure of the massive ice is horizontal to subhorizontal and concordant with the structure of the overlying sediments. These characteristics are more consistent with a segregation origin instead of burial of glacial ice (French, Reference French1998; French and Shur, Reference French and Shur2010; Lacelle and Vasil'chuk, Reference Lacelle and Vasil'chuk2013). The chemical composition of the ice also supports a segregation origin. The concentration of major ions in the tabular massive ice (tens to thousands parts per million range) is orders of magnitude higher than expected for firnified glacial ice (i.e., nearby Agassiz Ice Cap has ionic concentrations in parts per billion range; Fisher et al., Reference Fisher, Koerner and Reeh1995; Koerner et al., Reference Koerner, Fisher and Goto-Azuma1999). The geochemical facies (NaCl) and Na/Cl and DOC/Cl molar ratios in the massive ice suggest a contribution of seawater to the groundwater reservoir, especially for the lower-elevation sites (Dump and Station Creek). However, the low δ¹⁸O values (−35‰ to −25‰) of the ice indicate that, despite the addition of seawater, the main source of water for the ice is glacial meltwater. Ice formed by equilibrium freezing of water will typically have δD-δ¹⁸O regression slope values between 4 and 6, with the value largely depending on isotopic composition of initial water and freezing rate (Souchez and Jouzel, Reference Souchez and Jouzel1984; Lacelle, Reference Lacelle2011). However, the massive ice at the three sites has co-isotope slope values between 7.3 and 8.4, which at first sight would suggest a firnified ice origin (Fig. 6).

Freezing of water with δD-δ¹⁸O slope value near the global meteoric water line

In an open system where there is equilibrium freezing and recharge of the reservoir, Souchez and Jouzel (Reference Souchez and Jouzel1984) suggested that the value of the freezing slope (S) from an initial reservoir (r) that receives input of water (i) could be estimated from:

(1)$$S = \displaystyle{{{\rm \alpha }\left[{( {{\rm \alpha \;}-{\rm \;}1} ) ( {1000{\rm \;} + {\rm \;\delta Dr}} ) {\rm \;}-{\rm \;}\left({\displaystyle{{\rm A} \over S}} \right)( {{\rm \delta Di\;}-{\rm \;\delta Dr}} ) } \right]} \over {{\rm \beta }[ {{\rm \beta \;}-{\rm \;}1} ) ( {1000{\rm \;} + {\rm \;}{\rm \delta }^{18}{\rm Or}} ) -( {{\rm A}/S} ) ( {{\rm \delta }^{18}{\rm Oi\;}-{\rm \;}{\rm \delta }^{18}{\rm Or}} ) ] }}$$

where β = fractionation factor of ¹⁸O ice water, α = fractionation factor of D ice water, δDi = δD composition of input, δDr = δD composition of reservoir, δ¹⁸Oi = δ¹⁸O composition of input, δ¹⁸Or = δ¹⁸O composition of reservoir, A = coefficient for input, and S = coefficient for freezing.

This equation shows that the freezing slope depends on the initial δD and δ¹⁸O of the reservoir (which influences the value of the fractionation factor) and the difference in δD and δ¹⁸O values between the input and the reservoir. In most natural systems, the difference in δD and δ¹⁸O between the input and the reservoir is small, and the forming ice would develop a freezing slope (values between ca. 4 and 6, and lower than the meteoric water line). However, Souchez and de Groote (Reference Souchez and de Groote1985) found basal ice at Gruben-gletscher in Valais, western Switzerland, with a δD-δ¹⁸O slope of 8.3, much higher than predicted for open-system freezing but similar to the meteoric water line. Souchez and de Groote (Reference Souchez and de Groote1985) simulated the evolution of δD and δ¹⁸O in ice if the reservoir was being recharged with water having an isotopically lighter composition than the initial reservoir using Eq. 1. It was found that the δD-δ¹⁸O of the ice would plot along a meteoric slope, albeit with slightly lower D-excess values. It was therefore suggested that the glacial meltwater received additional input from an ice-dammed lake near the glacier margin that had an isotopically lighter composition. Another example of meteoric slope produced under an open freezing system that receives an isotopically light input is at the Mammuthöhle cave in the Alps of central Austria (Kern et al., Reference Kern, Fórizs, Pavuza, Molnár and Nagy2011).

The landscape model for the development of the tabular bodies of massive ice in the ESL would fit this condition of open-system freezing and where the groundwater reservoir is being recharged by water with a substantially different δD-δ¹⁸O composition. However, there is one difference with Souchez and de Groote (Reference Souchez and de Groote1985). In the ESL, the reservoir initially recharged by glacial meltwater is likely receiving some input of brackish seawater with a higher isotopic composition. In any case, the reservoir would be recharged by water whose δD-δ¹⁸O composition is either (1) being progressively depleted as the melting of the IIS progresses to the deeper and older ice with lower isotopic composition (i.e., δ¹⁸O transition from the Early Holocene to late Pleistocene age ice at Agassiz Ice Cap is in the order of 7–10‰; Fisher et al., Reference Fisher, Koerner and Reeh1995; Zdanowicz et al., Reference Zdanowicz, Fisher, Clark and Lacelle2002) or (2) enriched over the initial reservoir composed of glacial meltwater as it receives input of seawater, likely on the order of 15–20‰. Support for scenario 1 is provided from the ¹⁴C_DOC ages obtained from the tabular massive ice, where an increase in age is observed toward the sites at lower elevation (Fig. 7). This would suggest that as the land emerged, the reservoir was being recharged by the melting of the deeper-older Innuitian ice layers (i.e., the late Pleistocene ice layers). However, the lower-elevation sites also show a higher seawater contribution with respect to the Gemini site. Based on the TDS, the Dump and Station Creek sites likely received 1–10% contribution of seawater in the reservoir.

To demonstrate the effect of both scenarios on the value of the δD-δ¹⁸O regression slope of the forming ice, we used the Souchez and Jouzel (Reference Souchez and Jouzel1984) model (Eq. 1) and FREEZCH9, an isotope-augmented version of FREZCHEM with a recursive capability to mix water of fixed chemistry and δD-δ¹⁸O composition to the remaining reservoir (Faucher et al., Reference Faucher, Lacelle, Fisher, Weisleitner and Andersen2020; Fisher et al., Reference Fisher, Lacelle, Pollard and Faucher2020). The equilibrium fractionation factors for D and ¹⁸O during freezing (α_i-w) were those of O'Neil (Reference O'Neil1968), and we increased the difference in δ¹⁸O values between the input and the reservoir from 0‰ to 25‰ (equivalent of 0‰ to 200‰ for δD). For scenario 1 (recharge by an isotopically depleted source), if |δ¹⁸Oi − δ¹⁸Or| is small, the regression slope value is near the one expected for freezing; however, if |δ¹⁸Oi − δ¹⁸Or| increases to >10‰, the regression slope value during freezing approaches that of the meteoric water line (S = 8) (Fig. 8). For scenario 2 (recharge by an isotopically enriched source), if |δ¹⁸Oi − δ¹⁸Or| is small, the regression slope value is also near the one expected for freezing; however, if |δ¹⁸Oi − δ¹⁸Or| is 3‰, the regression slope value reaches ~14, and if |δ¹⁸Oi − δ¹⁸Or| continues to increase, regression slope value approaches that of the meteoric water line. The relative contribution of input to recharge under equilibrium conditions does not affect the findings; for example, the same results are obtained for 99% or 50% of residual water remaining in the reservoir and being recharged to the initial volume. At our three sites in the ESL, the tabular massive ice has co-isotope slope values between 7.3 and 8.4. This would suggest that |δ¹⁸Oi − δ¹⁸Or| was likely >10‰ and that possibly both scenarios could have occurred for the growth of the tabular massive ground ice bodies.

Figure 8. Numerical modeling of the effect of equilibrium freezing under open-system condition and recharge from an input (δi) with a different δD-δ¹⁸O composition relative to that of the initial reservoir (δr) on the value of the δD-δ¹⁸O regression slope. To demonstrate the effect of δi > δr and δi < δr on the value of the δD-δ¹⁸O regression slope of the forming ice, we used both the Souchez and Jouzel (Reference Souchez and Jouzel1984) model (Eq. 1) and FREEZCH9 (Faucher et al., Reference Faucher, Lacelle, Fisher, Weisleitner and Andersen2020; Fisher et al., Reference Fisher, Lacelle, Pollard and Faucher2020). For the simulations, δ¹⁸Or and δDr = −25‰ and −190‰, respectively, and δi was increased or decreased accordingly. The equilibrium fractionation factors for D and ¹⁸O during freezing (α_i-w) were those of O'Neil (Reference O'Neil1968).

Holocene permafrost evolution in the ESL and the growth of tabular massive ice in the raised marine-deltaic sediments

The Fosheim Peninsula was occupied by the IIS, which reached a thickness of ~1.6 km (Dyke et al., Reference Dyke, Andrews, Clark, England, Miller, Shaw and Veillette2002; England et al., Reference England, Atkinson, Bednarski, Dyke, Hodgson and Ó Cofaigh2006). Deglaciation in the ESL (10,300–8800 ¹⁴C yr BP [~12,100–9800 cal yr BP]; England et al. Reference England, Atkinson, Bednarski, Dyke, Hodgson and Ó Cofaigh2006) was followed by seawater incursion and the deposition of up to 35 m of marine-deltaic sediments over the weathered sandstone bedrock (8800–7800 ¹⁴C yr BP [~9800–8600 cal yr BP]; Bell and Hodgson, Reference Bell, Hodgson, Garneau and Alt2000). Marine regression and isostatic rebound later exposed the marine sediments to the atmosphere. Paleotemperature reconstructions from the Agassiz Ice Cap suggest that mean 25-yr air temperature was 1–3°C warmer than today between 7800 and 5000 ¹⁴C yr BP (~8600–5700 cal yr BP), thus in the −17°C to −15°C range for the ESL (Lecavalier et al., Reference Lecavalier, Fisher, Milne, Vinther, Tarasov, Huybrechts and Lacelle2017). The ¹⁴C_DOC measurements of ice wedges indicate that the air temperatures were sufficiently cold to allow for the aggradation of permafrost in the marine sediments immediately following marine regression (Campbell-Heaton et al., Reference Campbell-Heaton, Lacelle, Fisher and Pollard2021; Fig. 7). In addition, thermal modeling of permafrost aggradation during the Early to Middle Holocene in marine sediments of a fjord in Svalbard using mean annual air temperature in the −6 to −4°C range showed that permafrost could aggrade tens of meters in a relatively short time period (~200 yr) (Rotem et al., Reference Rotem, Lyakhovsky, Christiansen, Harlavan and Weinstein2022).

The development of tabular massive ice in the ESL raised marine-deltaic sediments involves glacial meltwater recharging an aquifer in the poorly consolidated weathered sandstone beneath the Holocene marine sediments. When ice sheets overlie permeable materials, such as the unconsolidated Tertiary sandstones and shales of the ESL, infiltration of subglacial meltwater into the bed and into the groundwater reservoir is expected (e.g., Boulton and Dobbie, Reference Boulton and Dobbie1993; Lemieux et al., Reference Lemieux, Sudicky, Peltier and Tarasov2008). Although cold-based glaciers are largely frozen to the bed, some may have areas of basal melting (Paterson, Reference Paterson1969). In addition, recent work from the Greenland Ice Sheet showed the importance of moulins for transferring surface meltwater to the subglacial zone (Gulley et al., Reference Gulley, Benn, Müller and Luckman2009; Catania and Neumann, Reference Catania and Neumann2010). For the ESL, the IIS meltwater recharging the aquifer might have been sourced from both surface and basal melt.

The groundwater in the aquifer would then migrate under a hydraulic and thermal gradient to the freezing front as permafrost aggrades in the marine sediments, allowing for the formation of thick tabular bodies of massive ice. However, permafrost aggradation and formation of massive ice in the marine sediments in the ESL would follow a spatiotemporal gradient because of the marine regression and isostatic rebound. Permafrost would first begin to aggrade at the Gemini site (120–125 m asl) between 8500 and 8000 ¹⁴C yr BP (~9500 and 8900 cal yr BP). At that time, the aquifer would have been recharged by meltwater of Early Holocene–age ice (δ¹⁸O: −27‰ to −25‰) and late Pleistocene meltwater (δ¹⁸O: −34‰ to −31‰) as the receding IIS was located in proximity to the ESL (Fig. 1). The massive ice at Gemini is very pure (few to no sediment inclusions) and has a thinner sediment overburden (<2 m). The TDS in Gemini ice are the lowest and have nearly the same major ion molar ratios as glacial ice from the Greenland Ice Sheet (Yde et al., Reference Yde, Knudsen, Hasholt and Mikkelsen2014). The fact that marine effects are minimal at this site is likely due to it being close to marine limit and still in proximity to a receding IIS at the time of permafrost aggradation.

Relative sea-level curves place the Station Creek and Dump sites (40–50 m asl) as emerging at approximately 5000 ¹⁴C yr BP (~5700 cal yr BP) (Fig. 7). The slightly lower δ¹⁸O values of the tabular massive ice at these sites would suggest that the groundwater reservoir was decreasing in volume as freezing of water imparts a progressive decrease in δ¹⁸O in the residual water. The decreasing reservoir was caused by the receding IIS (by 5000 ¹⁴C yr BP [~5700 cal yr BP], the IIS was constrained to the mountains along eastern Ellesmere Island) and continued permafrost aggradation at higher elevations. For example, at the elevation of Gemini (120–125 m asl), permafrost has been aggrading for ca. 3000 yr, and it probably reached a few hundred meters thick by 5000 ¹⁴C yr BP (~5700 cal yr BP). In addition to a decreasing groundwater reservoir, the combination of the IIS being located along the eastern mountains and thick permafrost likely caused a stoppage in glacial meltwater seepage to the reservoir. Instead, the groundwater reservoir was receiving leakage of seawater into the residual aquifer. The tabular massive ice at both Station Creek and Dump sites has Na/Cl molar ratios close to seawater, and TDS concentrations suggest a contribution of seawater on the order of 1–10%. The addition of seawater to the reservoir with higher δ¹⁸O values would also explain the near meteoric regression slope values of the massive ice. Overall, the groundwater aquifer in the poorly consolidated sandstone beneath the marine sediments appears to have experienced a switch from seepage of glacial meltwater during the Early Holocene to slow leakage of seawater during the mid-Holocene as a result of permafrost aggradation and isostatic rebound.