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Hydrologic modeling of a perennial firn aquifer in southeast Greenland

Published online by Cambridge University Press:  20 October 2022

Olivia Miller*
Affiliation:
Department of Geology and Geophysics, University of Utah, Salt Lake City, Utah, USA
Clifford I. Voss
Affiliation:
Scientist Emeritus, U.S. Geological Survey, Water Mission Area, Menlo Park, California, USA
D. Kip Solomon
Affiliation:
Department of Geology and Geophysics, University of Utah, Salt Lake City, Utah, USA
Clément Miège
Affiliation:
Geography Department, University of Utah, Salt Lake City, Utah, USA Department of Geography, Rutgers, The State University of New Jersey, New Brunswick, NJ, USA
Richard Forster
Affiliation:
Geography Department, University of Utah, Salt Lake City, Utah, USA
Nicholas Schmerr
Affiliation:
Department of Geology, University of Maryland, College Park, MD, USA
Lynn Montgomery
Affiliation:
Department of Atmospheric and Oceanic Sciences, University of Colorado, Boulder, CO, USA
*
Author for correspondence: Olivia Miller, E-mail: oliviamill@gmail.com
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Abstract

A conceptual model, based on field observations and assumed physics of a perennial firn aquifer near Helheim Glacier (southeast Greenland), is evaluated via steady-state 2-D simulation of liquid water flow and energy transport with phase change. The simulation approach allows natural representation of flow and energy advection and conduction that occur in vertical meltwater recharge through the unsaturated zone and in lateral flow within the saturated aquifer. Agreement between measured and simulated aquifer geometry, temperature, and recharge and discharge rates confirms that the conceptual field-data-based description of the aquifer is consistent with the primary physical processes of groundwater flow, energy transport and phase change. Factors that are found to control simulated aquifer configuration include surface temperature, meltwater recharge rate, residual total-water saturation and capillary fringe thickness. Simulation analyses indicate that the size of perennial firn aquifers depends primarily on recharge rates from surface snowmelt. Results also imply that the recent aquifer expansion, likely due to a warming climate, may eventually produce lakes on the ice-sheet surface that would affect the surface energy balance.

Type
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/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of The International Glaciological Society

1. Introduction

Ice-sheet mass loss represents a primary uncertainty in future projections of sea-level rise (Cazenave, Reference Cazenave2006; Le Bars, Reference Le Bars2017). Meltwater on an ice sheet can either run off or remain stored within the ice sheet as internal accumulation. Perennial firn aquifers temporarily store liquid water, much of which may eventually flow to the ocean (Forster and others, Reference Forster2014; Koenig and others, Reference Koenig, Miège, Forster and Brucker2014; Poinar and others, Reference Poinar2017; Miller and others, Reference Miller2020). Firn aquifers form when meltwater at the snow surface infiltrates into the firn and fills available pore space without refreezing during winter. This requires that sufficient pore space exists to store meltwater and that high snow accumulation insulates meltwater and prevents refreezing (Forster and others, Reference Forster2014; Kuipers Munneke and others, Reference Kuipers Munneke, Ligtenberg, van den Broeke, van Angelen and Forster2014). In ice-sheet accumulation zone areas unfavorable to aquifer formation (insufficient melt or accumulation), meltwater refreezes and does not contribute to mass loss to the ocean. Where firn aquifers form, they allow movement of accumulation zone meltwater along an elevation gradient, and permit meltwater discharge to the ocean should a connected hydrologic system develop. In Greenland, perennial firn aquifers cover ~20,000–90,000 km2 within the ~1200–2000 m elevation range (Forster and others, Reference Forster2014; Miège and others, Reference Miège2016; Steger and others, Reference Steger, Reijmer and van den Broeke2017a). In a firn aquifer, ‘groundwater’ refers to liquid water below the surface of and within the ice sheet or englacial water.

Firn aquifers affect multiple processes related to ice-sheet mass balance, including meltwater transport and possibly ice-sheet dynamics, although the magnitude of their effects is poorly constrained. Firn aquifer total liquid water volume estimates would cause ~0.4 mm of sea-level rise (Koenig and others, Reference Koenig, Miège, Forster and Brucker2014) if completely discharged to the ocean; however, sea-level rise resulting from the observed expansion (Miller and others, Reference Miller2020) and continued flow of meltwater through firn aquifers would be greater. Where meltwater reaches the ice-sheet base, it may reduce basal friction, allowing ice to move downslope more quickly (Poinar and others, Reference Poinar2017, Reference Poinar, Dow and Andrews2019). Thus, firn aquifer dynamics may also be of importance to glacial movement, which is an important contributor to sea-level rise. Hence, firn aquifers may play an important role in ice-sheet and glacier hydrology and processes of glacial mass transport and balance. Predicting the future of Greenland ice sheet (GrIS) mass balance thus requires improved understanding of the role that firn aquifers currently play in this balance, and how this may evolve under a warming climate.

Field work on the firn aquifer upslope from Helheim Glacier in southeastern Greenland (Fig. 1) as well as firn and regional climate modeling have provided basic initial data and analyses of general firn aquifer conditions including aquifer geometry and location (Forster and others, Reference Forster2014; Koenig and others, Reference Koenig, Miège, Forster and Brucker2014; Miège and others, Reference Miège2016; Montgomery and others, Reference Montgomery2017; Steger and others, Reference Steger2017b), firn stratigraphy, density, porosity and temperature (Koenig and others, Reference Koenig, Miège, Forster and Brucker2014; Killingbeck and others, Reference Killingbeck2020), hydraulic properties (Miller and others, Reference Miller2017), liquid water flow rates and residence times (Miller and others, Reference Miller2018, Reference Miller2020), liquid water volume (Legchenko and others, Reference Legchenko2018a, Reference Legchenko2018b), impacts of aquifer discharge to crevasses (Poinar and others, Reference Poinar2017), subglacial hydrology (Poinar and others, Reference Poinar, Dow and Andrews2019) and climatic conditions necessary for aquifer formation (Kuipers Munneke and others, Reference Kuipers Munneke, Ligtenberg, van den Broeke, van Angelen and Forster2014; Steger and others, Reference Steger, Reijmer and van den Broeke2017a, Reference Steger2017b).

Fig. 1. (a) Firn aquifer site map in southeastern Greenland and conceptual model of hydrology adapted from Miller and others (Reference Miller2020). Landsat 8 composite image of Helheim Glacier (21 August 2014) showing profile simulated and conceptual model applied in simulations in 1-D and 2-D. Elevation contours from Cryosat-2 DEM (Helm and others, Reference Helm, Humbert and Miller2014). (b) Firn aquifer geometry along simulated profile determined from mean 1-D velocity profiles (red line) obtained from seismic (solid black line, inversion of travel times) and radar (water table, upper dashed black line) surveys over a 15 km profile. Aquifer base was dertermined by probability of seismic veloicty increase (lower dashed black line); details are presented in Montgomery and others (Reference Montgomery2017). Simulated profile extends upslope beyond the seismic profile.

Meltwater production on the ice sheet is projected to increase as global temperatures rise, most likely increasing recharge and perhaps causing firn aquifers to expand. Firn-aquifer expansion has indeed been observed (Montgomery and others, Reference Montgomery2017; Miller and others, Reference Miller2020) and liquid water volume in the Helheim aquifer has increased with time (Legchenko and others, Reference Legchenko2018a). Increased meltwater production may also increase the supply of liquid water available to hydrofracture crevasses to the base of the ice sheet, pressurizing liquid water at the ice-sheet base and thereby possibly increasing ice-sheet velocity (Alley and others, Reference Alley, Dupont, Parizek and Anandakrishnan2005; Koenig and others, Reference Koenig, Miège, Forster and Brucker2014; McNerney, Reference McNerney2016; Poinar and others, Reference Poinar2017, Poinar and others, Reference Poinar, Dow and Andrews2019). Thus, understanding the fate of meltwater and the dynamics of liquid water flow through the firn aquifer is critical for predicting the ice sheet's response to climate change and, in turn, its impact on sea-level rise.

1.1. Prior firn hydrologic modeling

Typically, studies using numerical analyses to study liquid water flow in firn have used 1-D vertical models of firn thermodynamics and liquid water movement, often developed for modeling firn densification or other processes. However, these approaches (discussed below) are limited because they cannot consider lateral flow of liquid water, which is a key process that transports liquid water mass and energy in firn aquifers.

A range of snow and firn models have been applied to meltwater flow through firn. Regional climate models such as the Modèle Atmosphérique Regional (MAR, Gallée and Schayes, Reference Gallée and Schayes1994) or the Regional Atmospheric Climate MOdel (RACMO, Van Meijgaard and others, Reference Van Meijgaard, Van Ulft, Bosveld, Lenderink and Siebesma2008; Noël and others, Reference Noël2015) can be coupled to subsurface models to resolve meltwater retention and refreezing within snow (e.g. Fettweis, Reference Fettweis2007; Ettema and others, Reference Ettema2010; Reijmer and others, Reference Reijmer, Van Den Broeke, Fettweis, Ettema and Stap2012; Steger and others, Reference Steger, Reijmer and van den Broeke2017a, Reference Steger2017b). Many of these firn models are summarized in Stevens and others (Reference Stevens2020) and Vandecrux and others (Reference Vandecrux2020a, Reference Vandecrux2020b). For example, IMAU-FDM is a 1-D vertical model designed to couple with regional climate models to simulate firn density, temperature and liquid water content on polar ice sheets (Ligtenberg and others, Reference Ligtenberg, Helsen and Van Den Broeke2011). Kuipers Munneke and others (Reference Kuipers Munneke, Ligtenberg, van den Broeke, van Angelen and Forster2014) used IMAU-FDM to explain climatic and firn conditions that allow firn aquifers to form, namely high accumulation and high snowmelt rates.

To date, the application of firn models to firn aquifers has yielded useful, but rather limited success (Vandecrux and others, Reference Vandecrux2020b). Generally, model predictions of vertical firn temperature and liquid water content profiles do not match firn aquifer observations well. Firn model limitations stem from the fact that these models were primarily developed to represent processes such as densification in relatively dry firn, and not firn aquifers. The application of existing models to firn aquifers has several challenges including (1) Models do not fully or accurately represent the physical laws governing liquid water flow through porous media, instead using mathematical simplifications to represent such flow. (2) They are limited to 1-D-vertical-profile representation of what are really 3-D systems. Even where firn aquifers do not exist, lateral differences in meltwater recharge distribution and lateral heterogeneity in firn hydraulic properties would cause 1-D vertical firn models to provide poor representations of hydraulic and freeze/thaw processes in firn. (3) Existing models don't account for differences in liquid water flow physics between saturated and unsaturated zones (e.g. hydraulic conductivity variation with liquid saturation, and the impact of fluid pressure on water saturation). (4) They do not incorporate the physics, and impacts, of lateral liquid water flow on firn-aquifer configuration and dynamics. Some firn models (e.g. the DTU model) do not allow for the formation of firn aquifers at all (Sørensen and others, Reference Sørensen2011; Simonsen and others, Reference Simonsen2013; Vandecrux and others, Reference Vandecrux2020b).

To move liquid water through layers in a vertical column of firn, some firn models (e.g. Ligtenberg and others, Reference Ligtenberg, Helsen and Van Den Broeke2011; Van Pelt and others, Reference Van Pelt2012; Marchenko and others, Reference Marchenko2017) employ variations of ‘bucket-tipping’ schemes in which liquid water in a snow layer is moved to a deeper layer when the liquid water content exceeds a specific level (e.g. 2–6% of pore volume). This movement continues until the liquid water passes out of the model domain, or ‘runs off’, generally at depth (above an impermeable layer or at the bottom of the model domain). However, this ‘run off’ process does not include the physics of liquid water flow through porous media (either saturated or unsaturated), and therefore cannot represent flow through an aquifer or changes in the elevation of an aquifer's water table across any distance or time.

Some models do allow liquid water to move through firn according to more physics-based principles, although they are limited to vertical 1-D analysis. For example, SNOWPACK is a physically based snowpack model that simulates snowpack evolution, and can employ either a bucket-tipping or Richard's unsaturated-zone physics-based equation to simulate liquid water flow (including preferential flow paths) through snow (Wever and others, Reference Wever2015, Reference Wever, Würzer, Fierz and Lehning2016). Meyer and Hewitt (Reference Meyer and Hewitt2017) developed a continuum model for meltwater flow through snow following Darcy's law that allows for surface runoff if the snow is fully saturated. The subsurface models developed by Langen and others (Reference Langen, Fausto, Vandecrux, Mottram and Box2017) and Vandecrux and others (Reference Vandecrux2018, Reference Vandecrux2020a, Reference Vandecrux2020b) both include Darcy flow. Specifically, the subsurface scheme of the regional climate model HIRHAM5 (Langen and others, Reference Langen, Fausto, Vandecrux, Mottram and Box2017) was modified to account for evolution of firn density, albedo and hydraulic conductivity, and allows for liquid water retention in excess of the irreducible liquid saturation. It also incorporates a delayed runoff mechanism that allows liquid water in excess of the irreducible saturation to remain in a layer until it runs off or refreezes (Langen and others, Reference Langen2015, Reference Langen, Fausto, Vandecrux, Mottram and Box2017). For the application of the Community Firn Model to a firn aquifer, both slow matrix flow (Richard's equation) and preferential flow paths can be implemented, and at depth, no runoff is prescribed so liquid water accumulates to form an aquifer (Verjans and others, Reference Verjans2019; Stevens and others, Reference Stevens2020; Vandecrux and others, Reference Vandecrux2020b). However, vertical 1-D models that do allow the formation of a firn aquifer must include empirical terms that allow for a balance between liquid water accumulation and lateral flow, but such terms are not constrained by physics.

The groundwater flow model SEEP2D has been used to simulate 2-D liquid water flow in firn aquifers (Miège and others, Reference Miège2016; Montgomery and others, Reference Montgomery2020). Miège and others (Reference Miège2016) applied the model to the firn aquifer upslope from Helheim Glacier to simulate flow but used hydraulic conductivity values from mountain glaciers because this parameter had not yet been measured in the aquifer. Subsequent fieldwork showed that the measured hydraulic conductivity values in the aquifer upslope from Helheim Glacier are an order of magnitude higher than the values in mountain glaciers (Miller and others, Reference Miller2017). Montgomery and others (Reference Montgomery2020) used SEEP2D to evaluate recharge scenarios to a newly discovered firn aquifer in the Wilkins Ice Shelf. However, SEEP2D does not incorporate equations for representing heat transfer nor does this code simulate liquid water flow in the unsaturated zone. Although these efforts were able to represent general patterns of meltwater flow through the saturated zone, they neglected thermodynamic (such as freezing and thawing) and unsaturated zone processes, which are critical to understanding firn aquifer dynamics and to developing reliable forecasts of future firn aquifer behavior.

1.2. Study goals

This study is intended to (1) provide a test of the overall 2-D cross-sectional conceptual model (that includes a quantitative description of firn-aquifer physics including groundwater flow with energy transport and phase change) of the firn aquifer located upslope from Helheim Glacier (presented in Miller and others, Reference Miller2020) based on simulation analysis, (2) identify the primary processes that control aquifer configuration, and (3) evaluate how the aquifer configuration may change under continued warming of the Arctic that will likely cause increased recharge to the aquifer. The aquifer conceptual model describes the framework for understanding the system of liquid water movement from the snow surface through the firn. The framework includes the relationship between groundwater system components that affect the movement of liquid water, including recharge rates, firn stratigraphy and hydraulic properties, and water table elevations. Model results that differ substantially from field observations would indicate that the assumed physics and parameterizations or data are incorrect or incomplete. In contrast, model results that resemble field observations likely indicate that the model represents the appropriate physical processes that occur in a firn aquifer.

Given the relatively recent discovery of firn aquifers in Greenland, there were many uncertainties about their key physical processes at the outset of this study that warranted testing via numerical simulation. Does vertical infiltration of meltwater recharge the aquifer or does that liquid get stopped in the unsaturated zone by freezing? Using the conceptual model of the aquifer, can simulated lateral discharge rates match observations? Does the integration of observed vertical temperature profiles, water levels, recharge rates, firn physical properties such as porosity, permeability and stratigraphy, within a multi-dimensional numerical model that includes fluid and energy transport under both unsaturated and saturated conditions with phase change allow for simulation of a firn aquifer or do data and process representation deficiencies exist?

Although some of the modeling approach and results of this study evaluate basic processes and assumptions that are often assumed valid for mineral-based aquifers, it is not known that any of these apply to firn aquifers that are composed only of liquid water and ice. Therefore, given the lack of field and modeling studies of firn aquifers, and given that (in contrast with mineral-based aquifers) there is phase change between the frozen porous medium and the flowing liquid, a fundamental initial analysis is required to evaluate the physics and controlling parameters of firn aquifers. This analysis is the focus of the current study.

This is the first groundwater model of a firn aquifer in two spatial dimensions (2-D) that incorporates groundwater flow, heat transfer and phase change. This study employs a numerical simulation code called SUTRA-ICE, a modified version of SUTRA (Voss and Provost, Reference Voss and Provost2002), that simulates variable-density groundwater flow through unsaturated and/or saturated porous media and transport of solutes or energy. The code accounts for water freezing and thawing, allowing evaluation of whether or not the conceptual model represents self-consistent physics of the fluid mechanics and thermodynamics of groundwater flow and phase change in a firn aquifer.

Transient and steady-state simulations are based on, and compared with, field observations of key features of the firn aquifer upslope of Helheim Glacier, that include snow surface temperature and melt rates, firn temperature as it varies with depth, firn hydraulic conductivity, water-table depths and lateral aquifer extent. ‘Steady state’ refers to simulations where total liquid water recharge equals total liquid water discharge and no changes occur with time. The intention here is not to try matching the details of all field observations, but rather to match the general characteristics of the firn aquifer system as interpreted from the field measurements. This approach allows development of understanding of broad physical controls on aquifer shape and dynamics, despite the fact that there is a lack of temporally and spatially detailed data that would be required to underpin a detailed simulation of complex transient aquifer conditions in a heterogeneous firn aquifer.

This test of the conceptual model through numerical simulation is the first quantitative assessment of a firn aquifer conceptual model and application of SUTRA-ICE code to full snow and ice conditions. This use of SUTRA-ICE to simulate meltwater flow through firn is hoped to be a substantial advance in ice-sheet hydrologic modeling, and this paper presents a new type of simulation with both vertical and horizontal (fully 2-D) liquid water flow and heat transport under both unsaturated and saturated conditions with phase change. The primary controls on the existence and configuration of firn aquifers are identified on the basis of both 1-D and 2-D simulations, and implications of the simulated steady-state 2-D firn aquifer behavior in warmer climates with greater meltwater recharge are elucidated.

2. Methods

2.1. Firn aquifer conceptual model

The conceptual understanding for the formation and function of the Helheim Glacier perennial firn aquifer was initially formulated on the basis of field measurements and observations (2010–2017) and prior firn/crevasse modeling work. A description of this conceptual understanding is presented in Miller and others (Reference Miller2020) and is summarized just below and in Figure 1. The conceptual model developed in this study numerically describes that conceptual understanding, including a hydrogeologic framework, groundwater recharge, flow and discharge to crevasses, hydraulic, physical and thermal properties, and boundary conditions of the aquifer as well as the physical processes of saturated and unsaturated groundwater flow and freeze–thaw defined in SUTRA-ICE. Developing the conceptual model using SUTRA-ICE enables testing of how consistent the conceptual understanding is when constrained by internally consistent representation of physically based hydrologic processes including water mass and total energy balance in multiple spatial dimensions. Inconsistencies between the conceptual model and field observations in any part of the system would indicate field data or process representation deficiencies. The primary question to be answered by testing is: Can the conceptual model predict firn aquifer configuration and dynamics that are consistent with field observations, when providing the model with boundary conditions based on field measurement (primarily firn surface temperature and snow-melt recharge rate)?

Perennial firn aquifers form when sufficient surface meltwater infiltrates to depth, accumulates and saturates open firn pore space (Kuipers Munneke and others, Reference Kuipers Munneke, Ligtenberg, van den Broeke, van Angelen and Forster2014; Miller and others, Reference Miller2020). The heat contained in the infiltrating meltwater warms the shallow firn to the melting point through sensible and latent heat exchange, which keeps some water in its liquid state, permitting aquifer recharge to occur, and sustaining the liquid saturation within the saturated zone perennially. The upper ~10 m of the firn column, having the lowest liquid water content, experiences wide temperature variations as the firn cools through the fall, winter and spring months, and warms to ~0°C during the summer melt season (Koenig and others, Reference Koenig, Miège, Forster and Brucker2014; Miller and others, Reference Miller2020). Within the aquifer, temperatures remain near the melting point throughout the year as the existence of liquid water is sustained. Below the aquifer, temperatures decrease below 0°C and water is fully frozen (Miller and others, Reference Miller2020). The liquid water in the firn aquifer overlies fully frozen sub-aquifer ice.

The Helheim firn aquifer is recharged (9–30 cm a−1) during the summer melt season, as surface melt rapidly infiltrates through the firn unsaturated zone (0.4 m h−1) and into the saturated zone (Miller and others, Reference Miller2020). Mean specific discharge within the aquifer has been measured at 4.3 × 10−6 m s−1 (std dev. = 2.5 × 10−6 m s−1), and the aquifer has an average hydraulic conductivity of 2.7 × 10−4 m s−1 (Miller and others, Reference Miller2017, Reference Miller2018). The average lateral hydraulic gradient of the aquifer is 0.01 m m−1 (slope = 0.8°) (Miller and others, Reference Miller2018). Liquid water flows through the firn aquifer and discharges downslope, likely to crevasses near the edge of the ice sheet (Poinar and others, Reference Poinar2017; Miller and others, Reference Miller2020). The water table depth ranges between 5 and 50 m from the surface, and upslope from Helheim Glacier, the aquifer (i.e. the liquid-saturated zone above the low-permeability icy base of the aquifer) has an average thickness of 11 m (Forster and others, Reference Forster2014; Montgomery and others, Reference Montgomery2017). Porosity of the firn column decreases from ~60% at the snow surface to between 10 and 20% at the base of the aquifer (Koenig and others, Reference Koenig, Miège, Forster and Brucker2014). The model assumes this is disconnected porosity and therefore the aquifer base is a no-flow boundary. These hydraulic and aquifer physical properties were often derived from short-term observations and therefore knowledge of temporal variation is poorly constrained.

2.2. SUTRA-ICE numerical simulations

In this study, the pre-existing field data, observations and understanding, and the physics of freeze/thaw and liquid water flow represented by the SUTRA-ICE code comprise the conceptual model (described above and depicted in Fig. 1) that is evaluated in 1-D and 2-D (Fig. 2). The goals of the simulation analyses are to (1) use measured field data to calibrate and constrain the model in order to elucidate major controls on the aquifer and to confirm the viability of the combined descriptive and physical process-based conceptual model, and (2) to use the calibrated model to understand the general effects on the aquifer of increasing recharge that is expected to accompany increasing melt as the Arctic warms. The design of the current study emphasizes parsimonious modeling that is focused on capturing overall behavior in the face of limited field data, rather than attempting to apply complex and highly parameterized approaches, following the method described by Voss (Reference Voss2011). This approach supports understanding of the primary controls on the firn aquifer and effects of varying recharge.

Fig. 2. Two-dimensional cross-sectional model setup and boundary conditions. Top is located at upper surface of snow (‘ground’ surface), bottom is located at approximate depth where firn temperature is −1°C and liquid water has frozen into solid ice except irreducible liquid saturation with no connected porosity. Downhill boundary is located at a crevasse in which the water table is set at 20 m depth, and uphill boundary is located near upper extent of the observed firn aquifer. Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.

The SUTRA-ICE code, created by the U.S. Geological Survey, was one of the first of a group of cryohydrogeologic codes, developed over the past two decades (Rühaak and others, Reference Rühaak2015; Grenier and others, Reference Grenier2018), that couple groundwater flow equations to heat transfer equations with dynamic freeze–thaw capabilities. SUTRA-ICE represents the physics of the freeze–thaw process in groundwater where the liquid water can fully or partially saturate the porous medium. Details and governing equations are fully described in previous studies (McKenzie and others, Reference McKenzie, Siegel, Rosenberry, Glaser and Voss2007a; McKenzie and Voss, Reference McKenzie and Voss2013; Wellman and others, Reference Wellman, Voss and Walvoord2013; Kurylyk and others, Reference Kurylyk, Hayashi, Quinton, McKenzie and Voss2016; Evans and Ge, Reference Evans and Ge2017; Evans and others, Reference Evans, Ge, Voss and Molotch2018; Evans and others, Reference Evans, Godsey, Rushlow and Voss2020) and are not repeated here. Readers may refer to these publications for complete information about the code and its functioning.

SUTRA-ICE was originally developed for studies of groundwater flow in permafrost regions and in regions with seasonal subsurface ice. The code has been applied to a variety of cases considering seasonal ground ice and permafrost, how the formation and loss of subsurface ice interacts with the flowing liquid groundwater, and how both are impacted by hydrologic and thermodynamic processes at the ground-surface (McKenzie and others, Reference McKenzie, Voss and Siegel2007b; Ge and others, Reference Ge, McKenzie, Voss and Wu2011; McKenzie and Voss, Reference McKenzie and Voss2013; Wellman and others, Reference Wellman, Voss and Walvoord2013; Briggs and others, Reference Briggs2014; Kurylyk and others, Reference Kurylyk, MacQuarrie and Voss2014, Reference Kurylyk, Hayashi, Quinton, McKenzie and Voss2016; Evans and others, Reference Evans, Ge, Voss and Molotch2018, Reference Evans, Godsey, Rushlow and Voss2020; Lamontagne-Hallé and others, Reference Lamontagne-Hallé, McKenzie, Kurylyk and Zipper2018; Zipper and others, Reference Zipper, Lamontagne-Hallé, McKenzie and Rocha2018; Walvoord and others, Reference Walvoord, Voss, Ebel and Minsley2019; Rey and others, Reference Rey2020; Rushlow and others, Reference Rushlow, Sawyer, Voss and Godsey2020). The current study documents the first application of SUTRA-ICE to firn, in which only water in liquid and ice phases (no mineral grains) is present.

SUTRA-ICE has several advantages in simulating firn aquifers over other codes that have been applied to firn aquifers. SUTRA-ICE solves groundwater mass-balance equations for the unsaturated and saturated zones and allows for liquid water flow in one, two or three space dimensions (1-D, 2-D or 3-D). Representation of both vertical and horizontal flow in firn aquifer simulation is a significant advance beyond 1-D bucket-tipping, or even physics-based firn-water 1-D flow models because multiple dimensions allow for a dynamic, laterally extensive water table, representation of hydrologic and thermodynamic processes in both the unsaturated and saturated zones, and representation of liquid water flow through, and out of, the aquifer. Simulation of lateral liquid water flow is particularly important for representing a firn aquifer's saturated zone and aquifer discharge. This multidimensional capability can also be applied to simulate vertically and laterally heterogeneous firn, preferential flow paths and impermeable ice.

The SUTRA-ICE freeze–thaw capability accounts for the latent heat of fusion and varies thermal properties with changing total-water, liquid and ice saturations. Porosity is the fractional volume of void space in the porous medium (that can host liquid water and ice). ‘Saturation’ refers to the volume of total water (ice and/or liquid water), as a fraction of the volume of void space in the porous medium. ‘Total-water saturation’ is the sum of liquid water saturation and ice saturation. The code allows effective permeability to change as a result of phase change, with effective permeability decreasing as liquid water saturation decreases (due to drainage or freezing). The code does not simulate other possible processes that may occur in firn including cryosuction, air flow, vaporization and sublimation in unsaturated zones, and these represent sources of uncertainty in the model. Cryosuction has not been well studied in firn and is not expected to occur during the recharge period of the 1-D simulations or at all under the 2-D steady-state simulations, where no freezing occurs in the unsaturated zone. While cryosuction may be important during the transition to an isothermal unsaturated zone at 0°C, recharge during this transition is minimal and so cryosuction effects are expected to be minor. However, should cryosuction prove to be a significant process in firn aquifers, it could lead to some redistribution of liquid and ice contents in the unsaturated zone of a firn aquifer. Future experiments in firn might provide more certainty regarding the role of these other processes in firn aquifers. (Note that the version of SUTRA-ICE used was specifically modified for this project to output specific discharge, rather than liquid water velocity.)

In the case of a firn aquifer there is no rock-mineral phase and only liquid water and solid water (ice) exist, so special choices of SUTRA-ICE parameter values must be made. The mineral phase of the model domain is assigned as a permanent ‘ice backbone’ fraction that has the properties of ice. Seasonal snow cover porosity ranges between 0.4 for dense snow and 0.98 for freshly fallen, dry snow (Armstrong and Brun, Reference Armstrong and Brun2008), and in the current study, a range of backbone values from 0.3 to 0.6 (as a fraction of the total porous medium volume) is considered. The permanent ‘backbone’ of ice can never melt or change its value in a simulation. Saturation values refer to only the non-backbone void space – and ice saturation (which can vary during a simulation) does not include the backbone fraction. Lower backbone values can be simulated for cases in which more firn can melt than considered in this study (i.e. a lower backbone value can be specified to allow more firn melt). This approach can simulate very low backbone fractions (e.g. 0.001) but cannot simulate complete melting of the ice (a zero-valued backbone fraction), because if this were to occur there would be no porous medium (which requires the presence of both liquid and ice grains) to simulate. SUTRA-ICE simulations that approach this all-liquid state could be done by setting the backbone fraction to lower values; however, such results are not reported in the current study.

Within the pore space (e.g. for a backbone fraction of 0.4, the total non-backbone initial porosity is 0.6, which is among the lower values observed in firn), the saturations of liquid and ice vary spatially depending on simulated steady-state fluid pressure and temperature, according to freeze/thaw unsaturated-zone physics and prescribed state functions. The initial pore space can fill with liquid water and/or ice as the simulation progresses through time, depending on temperature, fluid pressure and available water.

The assigned properties of liquid water and ice are shown in Table 1. For discussions related to SUTRA-ICE simulations, ‘total water’ refers to both liquid and ice, ‘liquid’ refers to the liquid-water phase and ‘ice’ refers to the solid-water phase. These all refer to water/liquid/ice mass in the non-backbone volume of the firn. The backbone volume of ice remains constant throughout a simulation.

Table 1. Table showing general model specifications, boundary conditions and physical parameters used in 1-D and 2-D simulations

Three user-defined state functions are required for the physics description contained in the firn-aquifer conceptual model to describe how: (1) liquid water saturation (for fully saturated conditions) varies as a function of only temperature (providing the saturation of liquid and ice under fully saturated conditions); (2) total-water saturation varies as a function of only fluid pressure (defining unsaturated conditions, the saturations of total water and air in the firn pores); and (3) relative permeability varies as a function of liquid saturation (defining the fraction of total permeability of firn that remains as the liquid saturation decreases due to either drainage or freezing). Currently, no direct data exist to accurately define the saturation functions for Helheim firn aquifer, so estimates are based on observations of the system as well as results of 1-D simulations (Table 2). A variety of function types have been applied in coupled water and heat transport models with freeze–thaw, including simplified linear functions when detailed laboratory-derived functions are not available (Kurylyk and Watanabe, Reference Kurylyk and Watanabe2013). The functions, and their shapes, remain a matter of ongoing research and debate.

Table 2. Table showing model inputs and parameters for 1-D sensitivity analysis and simulations

In addition to the firn aquifer base cases, parameters were uniquely varied for each base case with high, medium, low and very low values. Bold values indicate base case variations.

The low salinity of aquifer liquid water (<50 μS cm−1) indicates that salinity that would allow liquid water to exist at temperatures much below 0°C is not present (Miller and others, Reference Miller2018). Therefore, the liquid water saturation function and values were selected because they enable freezing within a narrow range of temperatures; liquid water freezes according to a steep exponential freezing function (see Evans and Ge, Reference Evans and Ge2017, Eqn (1), where freezing temperature is 0°C).

Liquid water saturation for fully saturated firn conditions (S Lsat) varies with temperature according to the model adapted from Kozlowski (Reference Kozlowski2007) as:

(1)$$S_{{\rm Lsat}}( T ) = ( {1-\;S_{\rm r}} ) {\rm e}^{-( {T-T_{\rm f}/w} ) } + S_{\rm r}\;{\rm for}\;T < T_{\rm f}$$

where S r is the residual liquid saturation, T is temperature, T f is freezing temperature, and w is the exponential model parameter.

Total-water saturation (S w, the sum of liquid and ice phase saturations) is calculated with a piecewise-linear function that varies with pressure:

(2)$$S_{\rm W}( p ) = \left\{{\matrix{ {1\;{\rm for}\;p > p_{\rm e}} \hfill \cr {( {1-S_{\rm t}} ) \left({\displaystyle{{\,p-p_{\rm w}} \over {\,p_{\rm e}-p_{\rm w}}}} \right) + S_t\;{\rm for}\;p_{\rm w} \le p \le p_{\rm e}} \hfill \cr {S_{\rm t}\;{\rm for}\;p < p_{\rm w}} \hfill \cr } } \right.$$

where S t is the residual total-water saturation, p is pore pressure, p w is the pressure at which the linear segment of the function gives S w equal to S t, and all pressures are negative. This equation follows Evans and others (Reference Evans, Godsey, Rushlow and Voss2020), Eqn (2), where the air entry pressure (p e) is 0. When p > 0, the firn is fully saturated (S w = 1).

To determine the saturation of liquid, S L, in the firn unsaturated zone, it must be noted that the saturation of liquid water, S L, cannot exceed the total-water saturation, S W, even if Eqn (1) indicates a higher value. Thus,

(3)$$S_{\rm L} = \min \{ {S_{{\rm Lsat}}^{} ( T ) , \;\;S_{\rm W}( p ) } \} $$

The ice saturation, S I, is then given by

(4)$$S_{\rm I} = S_{\rm W}-S_{\rm L} = \max \{ {S_{\rm W}( p ) -S_{{\rm Lsat}}^{} ( T ) , \;\;0} \} $$

Relative permeability (k r) is calculated as a function of liquid-water saturation as:

(5)$$k_{\rm r} = ( {1-k_{\rm s}} ) S_{\rm s}^{} + k_{\rm s}$$

where k s is the relative permeability at residual liquid-water saturation and S s is a scaled liquid-water saturation defined as:

(6)$$S_{\rm s}^{} \equiv \displaystyle{{S_{\rm L}-S_{\rm r}} \over {1-S_{\rm r}}}$$

Relative permeability decreases linearly from a value of 1 when liquid saturation has a value of 1, to a minimum relative permeability value when the liquid saturation drops to the selected liquid saturation value at which this minimum occurs. For lower liquid saturations, the relative permeability remains at its minimum value (values are given in Table 1). Decreases in permeability due to freezing are calculated using a linear function to simulate observed permeability, which is relatively homogeneous (Miller and others, Reference Miller2017).

There is a current absence of field and laboratory data to constrain the functions for firn aquifers (Eqns (15)). However, this modeling study is not intended to represent the details of unsaturated zone water saturations and resulting relative permeabilities, as would a study that is focused on the details of an unsaturated zone in a typical hydrogeologic system. Rather, the current selections of simple linear relations for total-water saturation and relative permeability allow the current model to represent the primary saturation and drainage processes in a firn unsaturated zone. According to the functions, liquid water saturation decreases when temperature decreases, total-water saturation decreases when pressure drops and relative permeability decreases when liquid saturation drops. These simplifications represent the primary drainage and permeability changes and provide a basis for addressing the study goal of evaluating the major water and energy-balance processes that control the overall regional hydrologic behavior of a firn aquifer. However, such simplifications also represent a source of uncertainty in the modeling approach that future work may address.

The ice saturation, Eqn (4), in unsaturated conditions is determined by both the liquid water saturation, Eqn (3), and total saturation, Eqn (2), state functions (and is thus a function of both temperature and fluid pressure). The ice saturation state function appears as follows. For lower total water contents in the state function due to lower fluid pressure at constant temperature (for which the porous medium becomes more unsaturated), the liquid water content remains constant and ice content becomes lower. Kurylyk and Watanabe (Reference Kurylyk and Watanabe2013) explain that in laboratory measurements (Jame, Reference Jame1977; Watanabe and Wake, Reference Watanabe and Wake2009; Zhou and others, Reference Zhou, Zhou, Kinzelbach and Stauffer2014) the total unsaturated water content (which is a function of pressure) does not affect the liquid water content over a range of freezing temperatures. For example, this physical behavior can be observed in Figure 2 of Watanabe and Wake (Reference Watanabe and Wake2009), where, for a wide range of frozen soil types, the measured liquid water content depends only on temperature, and does not depend on the total-water saturation. Then, for lower total-water saturations at which there is no longer ice in the pores, the liquid saturation becomes equal to the total saturation and decreases with decreasing fluid pressure, as occurs in normal unfrozen mineral aquifer fabrics. This implies that the liquid-water saturation in partially frozen soils is independent of the total-water saturation, provided that the total-water saturation is greater than the maximum possible liquid saturation (the value that occurs for fully saturated conditions as a function of temperature). The current study assumes that similar state functions control unsaturated freeze–thaw behavior in firn, which contains no mineral grains, and this may represent a source of uncertainty in firn-aquifer modeling. Future studies could test this assumption in laboratory experiments on firn.

2.3. 1-D simulations

Calibration of model parameters employed in the 2-D cross-sectional steady-state model, described below, was achieved through analysis of 1-D time-variant simulations of firn temperature profiles. For the 1-D calibration, a variety of firn-aquifer situations were considered (Table 2). Three base cases were defined (drier firn, icier firn and wetter firn) and then input values were applied for high, medium, low and very low parameter-value variation cases (Table 2), resulting in a series of simulated vertical profiles of spring firn temperatures. The parameters and input values for total-water saturation, relative permeability and liquid water saturation equations from the combination that resulted in the closest match to measured firn temperature profiles were then employed in the 2-D steady-state simulations, described in the next section.

The 1-D vertical profile model analysis focuses on unsaturated zone freeze/thaw processes. Simulated temperature profiles were compared to measured temperature profiles for April 2016, based on a temperature string at FA15_1 (latitude: 66.3622, longitude: −39.3119, elevation: 1664 m) installed in April 2015 (Miller and others, Reference Miller2020). By August 2016, the surface temperature sensor had become buried ~1.5 m below the surface by new snow accumulation. A burial rate of 0.1 m month−1 was applied to the temperature sensor depths from 2015 to determine the sensor depth in April 2016. In reality, each sensor was deepened by ~1.2 m over this period. However, SUTRA-ICE observation nodes were set to occur at 1 m intervals, and so the measured depths are increased by only 1 m to coincide with SUTRA-ICE temperature observation nodes.

Transient April temperature profiles were simulated for a 1-D firn column consisting of a simple vertical stack of 2-D rectangular finite elements that provide the same 1-D vertical numerical results along the left and right edges of the stack of elements. The firn column simulation begins during the prior summer, when the firn column is isothermal at 0°C, and the water table is located at 20 m depth. Recharge of 0°C liquid water at the top of the column initially occurs in the simulation for 1.5 months, then stops. The liquid water is allowed to drain through the unsaturated zone for the first month, after which the snow surface temperature is lowered to a constant specified temperature value for 7 months, based on weather station data. The average air temperature for 2015 was −13°C and the average winter temperature for 2015 (January 1–April 30, and October 1–December 31) was −19°C (Reijmer and others, Reference Reijmer, Kuipers Munneke and Smeets2019). At the column base for all three periods, the temperature is held at 0°C (a specified-temperature boundary condition) and the fluid pressure is specified at a constant value of 294 300 Pa (equivalent to 30 m of hydraulic head, placing the simulated water table at 20 m depth, as observed in the field).

To characterize the effect of liquid water flow on the unsaturated zone temperatures under different parameterizations, dry, wet and icy firn base cases were established (Table 2). These base cases represent variations in parameters that control total and liquid water saturations. In the dry base case, the residual total-water saturation (ice + liquid) is low (0.01). In the icy base case, the residual total-water saturation is higher (0.20). In the wet base case, the minimum liquid saturation is high (0.20; this keeps more liquid water in the firn as the temperature decreases). For each of these base cases, the surface temperature during the winter, amount of summer recharge, fraction of backbone ice, unsaturated function, relative permeability function, and freezing function were varied over a range of values (see Table 2), providing a range of scenarios for each base case. Final simulated temperature profiles for each scenario were then compared to the measured firn temperatures.

2.4. 2-D simulations

2-D simulations were also developed and the aquifer response to changes in recharge was evaluated. The 2-D simulations represent the firn aquifer along a flowline of Helheim Glacier, where a series of sites provided surface-based measurements (Fig. 1) (Montgomery and others, Reference Montgomery2017; Legchenko and others, Reference Legchenko2018a). Each simulation was run in transient mode from arbitrary initial fluid pressure and temperature conditions until it reached a steady-state solution for liquid water pressure and temperature (same temperature value for liquid, ice and backbone), the two primary variables that are being solved for. The initial conditions and initial ice density vertical profile has no impact on the steady-state solution. The system of governing equations is inherently non-linear and running a transient simulation from arbitrary initial conditions to steady state resolves the non-linearities and provides the self-consistent numerical solution. The simulated 2-D cross-sectional domain consists of a 16 km long, 50 m thick vertical 2-D cross-section of the firn aquifer system (Fig. 2). The model configuration, the temperature and fluid pressure boundary conditions, as well as the freezing, unsaturated and relative permeability functions are explained in the following.

Regarding the spatial configuration and position of the model domain, there are two ways to accommodate glacial motion in the 2-D cross-sectional firn aquifer model. (1) It may be considered that the model domain moves downslope at the velocity of glacial movement with no new ice entering or leaving the cross-section; thus, the energy and water mass contribution of the moving glacier in which the firn aquifer exists would be zero. (2) If the model domain is set in a fixed location in space, the glacial ice moves through this fixed location, but in fact, the contribution of ice entering the upstream boundary and exiting the downstream boundary to the water mass and energy balances is negligible relative to that of the meltwater flux and vertical energy transport resulting from top-surface and bottom-surface temperature values. Therefore, the ice flow could be ignored in model simulations, and a fixed location of the model domain (2) was used for simplicity.

Boundary conditions and other details of firn-aquifer model setup are as follows. Meltwater generated at the surface of the snow was applied along the top boundary of the model as a specified fluid source boundary condition. Although non-uniform recharge occurs in the field, for simplicity in this initial firn-aquifer modeling study, recharge was applied uniformly across the top of the model, and the recharge rate is held constant during each simulation. Following confirmation of the conceptual model of a firn aquifer in the first 2-D simulations, the recharge rates, based on melt and recharge rates estimated from weather station data (Miller and others, Reference Miller2020), were varied in another set of runs (5 and 30 cm a−1) to determine their impact on the configuration of the firn aquifer.

The downslope model domain boundary was placed at the upslope edge of an open crevasse in the Helheim Glacier, where liquid water can flow out of (or in to) the aquifer. The hydrologic condition assumed at the crevasse was based on the measured water-table location at 20 m depth near the crevasse (Miège and others, Reference Miège2016). The water table along the upslope side of the crevasse was simulated by setting a specified fluid pressure of 0 Pa at the water table location (20 m depth) and by specifying hydrostatic fluid pressure values everywhere along the crevasse boundary (with hydrostatic pressures becoming more negative along the crevasse boundary above the water table and becoming greater positive values with greater distance below the water table). The linear hydrostatic pressure distribution along the crevasse wall was calculated assuming a constant density of liquid water at 0°C, of 1000 kg m−3. (Note that liquid water density was held constant for all simulations, in order to preserve simplicity by avoiding natural convection of liquid water due to density differences.) Liquid water could theoretically flow in the upslope direction into the aquifer at the simulated crevasse boundary during any period in which the water level in the crevasse was higher than the water level in the aquifer, although this scenario was not evaluated and the simulations reported here have only aquifer outflow at this boundary.

The temperature specified at the base of the cross-section (top of assumed impermeable ice) was held constant at −1°C, based on vertical temperature profile measurements (Miller and others, Reference Miller2020). The temperature specified at the snow surface was held at 0°C to match the temperature (also 0°C) of the liquid-water recharge added at the snow surface. Although measured surface temperatures decrease below 0°C when there is no meltwater recharge, the surface temperature remains at about 0°C during recharge periods. This choice was deemed appropriate for steady-state simulations.

Initial permeability values were set at 2.7 × 10−11 m2 based on field measurements of hydraulic conductivity (Miller and others, Reference Miller2017). The longitudinal dispersivities were set to the lowest value (usually about one-fourth of the element size measured in the direction of flow) that avoids instability in the numerical energy-transport solution.

The user-defined function values for total-water saturation, relative permeability and liquid water saturation in the 2-D simulations were determined based on the 1-D simulation results (Table 3). The dry base case function values were selected for 2-D simulations because they produce firn temperature profiles similar to observed temperature profiles and they are more similar to field observations than the wet base case. In the assumed functionality, irrespective of how low the fluid pressure becomes, a 1% total-water saturation (liquid plus ice) was retained in the firn pore space (backbone fraction was set at 0.4) as the total residual water saturation. Liquid water freezes according to a steep exponential freezing function ranging from 100% liquid at 0°C to the residual liquid saturation at −0.2°C. For possible future simulation analyses, note that a steep linear function would likely give similar simulation results as were obtained using this function. As liquid freezes, the effective permeability, given by the product of total permeability for fully saturated firn and the relative permeability, decreases linearly from the total permeability value when fully saturated to a value 100 times lower when liquid saturation is at its minimum-possible value. The decrease by a factor of 100 is based on experience in mineral soils, and although this value is arbitrarily selected for this analysis, it provides a simple but significant decrease in the ability of liquid water to flow through firn when the liquid saturation deceases to very low values.

Table 3. Table showing backbone and user-defined function values used in 2-D simulations

3. Analyses and results

3.1. 1-D simulations

By producing a variety of firn vertical temperature profiles, the 1-D simulations provide insight into the controlling parameters of the system and the major processes occurring (Fig. 3). The simulated temperatures for the dry and wet base cases most closely match the measured April temperature profile (Fig. 3a). Inspection of differences and similarities among these results, as discussed below, indicates that the most important input parameters that control simulated firn temperature profiles are surface temperature, residual total-water saturation (minimum saturation of liquid water plus ice) and thickness of the capillary fringe (only if the capillary fringe reaches the snow surface so there is no zone at irreducible total-water saturation). The capillary fringe is the zone between the unsaturated and saturated zones where pores are saturated, but the pressure head is less than atmospheric. Further inspection indicates that less important parameters controlling firn temperature are the backbone fraction and freezing function parameters, but only for the icy cases. The simulated firn temperature profile in most cases is not sensitive to changes in recharge from the prior summer, backbone fraction or relative permeability function (Fig. 3b).

Fig. 3. Simulated and measured firn temperature. (a) Simulated firn temperature from the icy, wet and dry base cases and icy case with winter surface temperature of −5°C. Dry and wet base case results overlay one another. (b) Simulated dry base case compared to measured firn temperature profile for a range of parameters that simulated firn temperature is insensitive to. All results overlay one another. (c) Simulated firn temperature from the dry base case with a range of winter surface temperature compared to measured firn temperature, (d) and simulated firn temperature from the dry base case with a range of residual total-water saturation (unsaturated function) values compared to measured firn temperature. Simulated firn temperature is most sensitive to winter surface temperature and the residual total-water saturation in the total-water saturation function.

Simulated firn temperature is sensitive to the winter surface temperature (Fig. 3c). The simulated firn temperature becomes significantly warmer or colder than the measured firn temperature, depending on the snow surface temperature in the winter (Fig. 3c). The coolest winter surface temperature tested, −20°C, results in a substantially cooler firn than observed, although the differences are greatest at the snow surface where measurements are lacking, making comparison difficult (Fig. 3c). However, assuming the measured temperature line slope is constant to the snow surface, surface temperature differences are estimated to be >5°C. Simulated firn temperatures with a surface temperature of −13°C align closely with measured firn temperatures (Fig 3c). Large temperature differences between measured and simulated temperatures also occur with the icy base case, and a winter surface temperature of −5°C (Fig. 3a) in which simulated firn temperature is up to 4.9°C warmer than that measured, indicating that total water content (liquid and ice) is important as well.

Simulated firn temperature is also sensitive to parameters controlling total water content in the unsaturated firn including the residual total water content and the thickness of the capillary fringe (Fig. 3d). Higher residual total-water saturation values result in warmer simulated firn temperature compared with measured temperature. This is shown in Figure 3a, where simulated temperatures under the icy base case are warmer than dry base case simulated temperatures and measured temperatures. This is also shown in Figure 3d, which shows how variation in residual total-water saturation influences simulated temperatures. When the capillary fringe is set to include the entire unsaturated zone (i.e. the ‘high’ variation of each base case), the increased liquid water content results in warmer simulated firn temperature of up to 2°C for the dry case, 3°C for the icy case and 1°C for the wet case.

3.2. 2-D simulations

Two primary results are obtained from the 2-D simulations. First, agreement between modeled and observed aquifers demonstrates that the conceptual model captures the primary processes and parameters that control the firn aquifer. Second, as recharge rates increase, the aquifer expands.

3.2.1. Description and comparison of modeling results to field observations

Using the total-water saturation, relative permeability and liquid water saturation function parameters determined from the 1-D analysis, the 2-D cross-sectional model of the firn aquifer was run in a transient simulation from arbitrary initial conditions until it reached approximate steady-state conditions. A stable firn aquifer was formed in the simulation (see Figs 4–6 for a recharge rate of 15 cm a−1). The system has an unsaturated zone of porous firn overlying a saturated zone where liquid fills pores above an ice zone where pores are filled with ice. The aquifer saturated zone (measured from its base, where ice saturation is at its maximum value and liquid water saturation is at its lowest possible value) to the water table (which occurs at some depth below the top of the cross-section) thins upslope. Temperatures within the simulated 2-D aquifer are at or just below 0°C, and are below 0°C below the aquifer base. The recharging snowmelt liquid water flows nearly vertically downwards (while undergoing freezing/thawing) through the firn's unsaturated zone overlying the aquifer, until the liquid reaches the saturated zone. At the firn-aquifer water table, the simulated meltwater naturally becomes part of the saturated zone of the aquifer, and the liquid water flows laterally (approximately parallel to the glacial surface slope) within the saturated zone, also with concomitant freezing or thawing. Simulated specific discharge rates (volume of liquid water in m3 flowing through a 1 m2 cross-sectional area of firn, per second of time) range from 1.5 × 10−9 to 7.6 × 10−6 m s−1. The liquid water discharges at the crevasse location along the downslope edge of the model domain.

Fig. 4. Simulated fluid pressure and firn temperature for three recharge rates (5, 15 and 30 cm a−1). The water table occurs where the fluid pressure is zero (shown in blue-white boundary on the pressure plot). Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.

Fig. 5. Simulated liquid saturation, ice saturation and total-water saturation (liquid plus ice) for three recharge rates (5, 15 and 30 cm a−1). Liquid and ice saturations are the volume of liquid and ice per volume of pore space, respectively. Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.

Fig. 6. Simulated firn aquifer showing liquid saturation, specific discharge and logarithm of specific discharge, to visualize near-vertical flow through the unsaturated zone and lateral flow through the saturated zone for three recharge rates (5, 15 and 30 cm a−1). The region of transition from maximum to minimum liquid saturation around the aquifer is very narrow. Specific discharge is a product of fluid velocity, firn total porosity, and, liquid-water saturation, sometimes referred to as ‘Darcy velocity’. Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.

Agreement between measured and simulated aquifer geometry, temperatures and discharge confirms that the conceptual understanding of the Helheim Glacier firn aquifer is reasonable (see 4.2 for discussion of this comparison). Note that observations represent a system not at steady state and therefore may differ from results of the system simulated at steady state. Therefore, a general comparison of spatial patterns and rates is provided.

The 2-D steady-state simulation (recharge rate = 15 cm a–1) produces a saturated zone that has generally the same geometry as the observed Helheim Glacier firn aquifer, where recharge has been estimated to range between 10 and 30 cm a−1. In the observed system, an unsaturated zone overlies a saturated zone, and the base of the aquifer is formed by ice. The aquifer thins upslope. In the simulated system, an unsaturated zone overlies a saturated zone, and the base of the aquifer is formed by ice. The aquifer thins upslope. Observed water table depths range from 5 to 50 m, and simulated water table intersects the snow surface. Observed water table undulations were not simulated, potentially because simulations do not include spatial variation in recharge along the snow surface slope, snow surface slope variations or 2-D heterogeneity in firn physical properties. However, the overall patterns of liquid, ice and total saturation agree in that the unsaturated zone overlies the saturated zone, and ice forms the aquifer base. For more detail, see a comparison of Figures 4 and 5 (15 cm a−1 recharge rate) with Figure 1b and also with Figure 10 in Miège and others (Reference Miège2016) and with Figure 4 in Montgomery and others (Reference Montgomery2017).

Vertical temperature profiles within the 2-D simulations agree with observations. Temperatures within the simulated 2-D aquifer are perennially at or just below 0°C, and cool below 0°C below the aquifer base. Observations of vertical firn temperature profiles indicate that within the aquifer, temperatures remain at or near 0°C throughout the year and sustain liquid water, and below the aquifer temperatures decrease below 0°C and water is fully frozen (Miller and others, Reference Miller2020).

Simulated fluid flow rates and patterns agree with observations. Simulated specific discharge rate ranges (1.5 × 10−9 to 7.6 × 10−6 m s−1) are similar to measured values, and show similar vertical profiles as are reported in Miller and others (Reference Miller2018). Measured specific discharge was highest at the top of the aquifer (~5 × 10−6 m s−1) and generally decreases with depth toward the bottom (~1 × 10−7 m s−1), with an average specific discharge of 4.3 × 10−6 m s−1 (σ = 2.5 × 10−6 m s−1) (Miller and others, Reference Miller2018). The agreement between modeled and observed aquifer characteristics of geometry, temperature and discharge using a relatively simple representation of the physics and physical characteristics of the aquifer instead of mere fitting of many parameter values or an overparameterized model representation, suggests that this model of the firn aquifer includes and adequately represents the primary processes controlling the aquifer.

3.2.2. Aquifer response to changes in recharge rate

A series of simulations was run with a range of mean annual recharge rates to understand the effects of changing recharge on the general configuration of the steady-state saturated zone in firn aquifers. Results (Figs 4–6) show that the geometry of the firn aquifer's saturated zone varies with recharge rate. This is similar to what would be expected to occur in mineral aquifers, but for firn aquifers, where liquid and ice saturations depend not only on total porosity and recharge rates, but also on freezing and thawing and, thus, temperature, this relationship was untested. Should increased recharge cause an increased total porosity of the firn via melting, then the amount of water-table rise or aquifer expansion upslope from an increased recharge rate might not be as great (maybe none) as would be expected in a mineral aquifer, should some (or all) of the extra recharge fit into the newly created pore space. This is one of the unique behaviors that may occur only in firn aquifers and the relation of porosity dependence on flow rate and temperature is a main functionality of the numerical model.

Simulations show that the steady-state saturated zone reaches higher upslope and the water table is higher at increased recharge rates, whereas the saturated zone occurs lower downslope with a deeper water table at reduced recharge rates (compare 5–30 cm a−1 in Figs 4–6). For cases with high-enough recharge (≥15 cm a−1), the steady-state simulated water table intersects the snow surface. For high-enough recharge rates, the water table intersects the snow surface along the entire slope (see case of 30 cm a−1).

4. Discussion

4.1. Insight into the controls on long-term meltwater retention and flow within firn

Scenarios representing variations in base model conditions and aquifer recharge rates were evaluated to learn the factors that control long-term meltwater retention and flow within firn. The cryohydrogeologic factors that control firn temperatures and aquifer configuration (water-table location and saturated-zone volume) are found to be as follows: (1) surface temperature, (2) meltwater recharge rate, (3) residual total-water saturation (minimum saturation of liquid water plus ice) and (4) thickness of the capillary fringe (only if it extends to the snow surface).

  1. (1) The results of the 1-D transient simulations highlight the importance of surface temperature controls on firn temperature, and the sensitivity that firn may have to rising temperatures under a warmer climate. Surface temperature determines melt rates and influences firn column temperatures throughout the year. Warmer surface temperatures allow for more surface melting and reduce wintertime firn column cooling.

    The sensitivity of firn temperatures to surface temperatures in simulations can be explained by the established physics included in model code. Phase change is an important process that controls firn temperature profiles. Without phase change, cold winter surface temperatures would propagate downwards into the firn via heat conduction, dropping temperatures at depth to many degrees below 0°C. However, phase change from liquid water to ice requires thermal energy (latent heat) and occurs in a very small temperature range just below 0°C (here considered to −0.2°C), which keeps the local firn temperature in this range as long as winter freezing (and summer thawing) is occurring. Warmer air temperatures can therefore warm firn temperatures by both increasing liquid content (and associated thermal energy) from increased snowmelt rates, as well as by reducing firn cooling during winter months due to higher surface temperatures.

    Subsequent increased liquid water content, in the capillary fringe and/or in the saturated zone, retains more thermal energy in the firn column throughout the year via both sensible heat and latent heat, and buffers the winter cooling, resulting in warmer firn temperatures. Thus, the elevated liquid-water content due to increased snowmelt rates also impedes winter firn cooling, resulting in warmer simulated unsaturated firn temperatures. Dry firn has much larger yearly temperature variation than does firn that contains more liquid water. The firn in the saturated zone remains at or just below 0°C throughout the year due, in part, to the high liquid water content.

  2. (2) Recharge rates correlate with surface temperatures. Aquifer response to potential climate change can be forecast because changes in snowmelt recharge rates corresponding to changes in surface temperature and solar radiation cause aquifer volume changes. Snowmelt rates are expected to rise under a warmer climate, potentially leading to increasing overall recharge rates, which would result in thicker firn aquifers. With enough additional recharge, the water table is projected to rise to the snow surface, forming lakes or rivers.

  3. (3) Increased residual total-water saturation results in warmer simulated firn temperatures at the end of the winter cold season. The effect of increasing the residual total-water saturation is to add total water mass that stores more thermal energy (both sensible and latent). This causes slower seasonal temperature changes in the unsaturated firn column.

  4. (4) Similarly, when the unsaturated zone properties are such that the capillary fringe reaches the snow surface (higher fluid pressure at residual liquid saturation), the increased liquid content throughout the firn column retains more thermal energy, resulting in greater thermal inertia. This causes firn temperatures at depth to lag behind surface temperature changes.

A range of approaches to formulating liquid-water saturation and relative permeability have been applied in unsaturated flow simulations and there is uncertainty in optimal function specification. However, sensitivity analysis demonstrates that firn temperature profiles are not sensitive to these functions. For example, no changes in the simulated vertical temperature profiles result from increasing the minimum liquid saturation by a factor of 10 or increasing the exponential model parameter by a factor of 100 in the liquid water saturation function or increasing the relative permeability at residual saturation in the relative permeability function by a factor of 500 (Fig. 3). This indicates that these choices of simplified state functions for liquid water saturation and relative permeability do exactly what was intended: to represent the most important freezing and permeability processes that control the aquifer configuration and primary dynamics. For this initial multidimensional analysis of firn aquifer physics, these selections have allowed a successful basic evaluation of firn aquifer configuration and response.

4.2. Surface water expression and implications of higher recharge rates

Although water levels vary within the aquifer with time, generally corresponding to melt rates (Miège and others, Reference Miège2016; Miller and others, Reference Miller2020), the difference between model and observed water table depths for the steady-state simulation with 15 cm a−1 recharge suggest that the aquifer is not in equilibrium currently (i.e. not at steady state) for current climatic conditions. This is similar to a firn aquifer in the Wilkins Ice Shelf that does not appear to be in equilibrium based on simple fluid flow modeling that does not consider thermodynamics (Montgomery and others, Reference Montgomery2020). As surface melt and recharge increases under a warming climate, the firn aquifer saturated zone is expected to grow in volume. The simulation-predicted inland aquifer expansion with greater recharge rates broadly agrees with SNOWPACK firn simulations (Steger and others, Reference Steger, Reijmer and van den Broeke2017a) as well as with observed inland expansion (Montgomery and others, Reference Montgomery2017; Miller and others, Reference Miller2020).

For recharge rates similar to those observed in the Helheim Glacier field area (15 cm a−1), the modeled steady-state water table intersects the snow surface (Figs 4–6) and this would generate surface water features such as streams and lakes. In land-based hydrologic systems, lakes and streams occur at locations where water tables intersect the land surface. The snow surface topography, which features slope variation between 0 and 2° (Miège and others, Reference Miège2016), would control the surface water feature type. Snow surface topography can be controlled by underlying subglacial topography or basal friction (Gudmundsson, Reference Gudmundsson2003; Sergienko, Reference Sergienko2013). Lakes could form in local topographic depressions and streams could form where the snow surface slopes more continuously downhill. The water table is generally closer to the snow surface at local surface topographic lows where lakes would form (Miège and others, Reference Miège2016).

Currently, firn aquifers and supraglacial lakes rarely co-occur (Koenig and others, Reference Koenig2015; Miège and others, Reference Miège2016). Southeast Greenland generally has few lakes compared to other parts of the ice sheet (Sundal and others, Reference Sundal2009; Selmes and others, Reference Selmes, Murray and James2011) and the absence of lakes in southeast Greenland has been attributed to steeper snow surface slopes (Sundal and others, Reference Sundal2009). At the Helheim field site, there is no evidence of streams or lakes. The ice sheet in southeast Greenland is characterized by thick permeable firn and relatively steep snow surface slopes that facilitate meltwater infiltration and aquifer formation and hinder surface water formation. These permeable firn conditions hinder the formation of streams and lakes by preventing meltwater from ponding and flowing along the low permeability ice surface, which, in contrast, occurs elsewhere on the GrIS (Echelmeyer and others, Reference Echelmeyer, Clarke and Harrison1991; Selmes and others, Reference Selmes, Murray and James2011; Smith and others, Reference Smith2015, Reference Smith2017; Chen and others, Reference Chen, Howat and De La Pena2017). Over time however, under current recharge conditions, the steady-state simulation results indicate that the water table in the Helheim firn aquifer may rise to the snow surface, forming lakes or streams. Thus, should the current climatic conditions persist and climate warming continue, streams or lakes may eventually appear in areas where firn aquifers intersect the snow surface.

Formation of such surface streams or lakes would dramatically alter the surface energy balance, possibly contributing to increased melt via reduced albedo. A surface hydrologic system of streams would presumably enhance flow of meltwater from the ice sheet to the ocean as well. Cold winter air temperatures could also freeze shallower liquid water in a firn aquifer, potentially forming thick ice slabs (MacFerrin and others, Reference MacFerrin2019), which may locally impede deep infiltration of snow melt.

This prediction of groundwater discharge at the snow surface highlights the critical link long-observed in land-based hydrology between surface water (supraglacial) and groundwater (englacial) hydrology, where they are considered a single ‘resource’ (Winter and others, Reference Winter, Harvey, Lehn Frank and Alley1998), that has not yet been emphasized in ice-sheet hydrology. Much emphasis has been placed on the connection between supraglacial and subglacial hydrology and the associated relevance for ice dynamics (Joughin and others, Reference Joughin, Tulaczyk, Fahnestock and Kwok1996; Zwally and others, Reference Zwally2002; Das and others, Reference Das2008), but as surface mass-balance processes have become the dominant control on ice-sheet mass loss and contribution to sea-level rise (Enderlin and others, Reference Enderlin2014), the link between supraglacial and englacial hydrology also becomes more important.

Increased surface melt will likely increase discharge from firn aquifers, possibly resulting in a greater direct contribution of this fluid to sea-level rise as mentioned above. Increased aquifer discharge could also generate new and deeper crevasses via hydraulic fracturing due to elevated standing water levels in existing cracks and crevasses. Increased aquifer discharge to crevasses that reach the glacier base could also lead to increases in glacier movement via increases in sub-glacial fluid pressure and concomitant decreases in sub-glacial friction due to groundwater water discharge to crevasses.

4.3. Future work

As an approximation of general conditions and behaviors of the firn aquifer system that is based on full multidimensional hydraulic and thermodynamic physics, the steady-state simulations provide a robust test of the physical self-consistency of the conceptual firn-aquifer model and provide insight into the main factors that control the configuration of firn aquifers. However, the steady-state 2D simulations considered here do not incorporate time-varying or spatially varying surface temperature and recharge, snow accumulation, firn burial, preferential flow paths through heterogeneous firn or possible localized perching of meltwater upon discontinuous ice lenses above the water table that occur in reality. As a result, these results do not account for complexities of percolation zone processes including the heat and liquid that goes into warming the cold unsaturated zone in the spring or winter accumulation and cold content addition. Future work could implement time-variable surface temperatures and recharge and the impact of ice layers in firn on infiltration and firn aquifers. Field and lab studies to constrain the total-water saturation, liquid water saturation and relative permeability functions, as well as the possible effects of cryosuction on liquid and ice saturation distributions, would allow future modeling to study firn aquifers with more local detail, especially in the unsaturated zone. Such advances would improve estimates of aquifer volume changes and discharge, aid in study of crevasse hydrofracturing and improve estimates of pressurization of basal (sub-glacial) meltwater that may increase glacial motion, which in turn may increase the global rate of sea-level rise.

5. Conclusions

This study presents the first numerical simulation of multi-dimensional liquid water flow and thermal energy transport with a code (SUTRA-ICE) where groundwater can freeze and thaw depending on ambient temperature and also on fluid pressure when freezing occurs in an unsaturated zone. Firn aquifers should be represented by multi-dimensional models that allow for the substantial lateral fluid flow and energy transport that define them. This code provides the requisite self-consistent hydraulic and thermodynamic physics basis, and it was used in this initial study to test the conceptual model of the firn aquifer upslope from Helheim Glacier, identify primary processes and factors that control overall firn aquifer configuration, and evaluate long-term firn aquifer configuration as a function of meltwater recharge rate.

As in all mathematical descriptions of physical processes, a description can and should be tested for its ability to reproduce observations, and if it does so successfully, this particular description is an acceptable representation of the modeled system. This result never proves that the description is the only one that will reproduce observations – but it indicates that this particular model stands as a feasible and useful description of the system. Perhaps, in the future, this particular description will be unable to reproduce new data that may be collected, limiting the usefulness of the description. There may also be other different mathematical descriptions that reproduce the currently existing data, and as such, these too may be considered as acceptable representations of the modeled system. Thus, the conceptual model presented here that includes a mathematical description of firn-aquifer behavior may be considered as an acceptable description.

Another ambiguity in postulating a mathematical description of a physical system is that, given enough parameters in the description, the ability of the description to fit measurements may be due primarily to the large number of parameters, which may allow even a model that only poorly describes the main physical processes to fit the measured data. For the current firn-aquifer model, this (over-parameterization) was avoided by keeping the number of parameters as low as possible and by representing the physical system as simply as possible, forcing the dynamics of the specific physical processes included in the conceptual model to fit the data as well as possible. The result here is that the conceptual model, and the physics it represents, is a strong descriptor of firn-aquifer configuration (especially for steady-state conditions in 2-D cross-sectional representations of these systems).

This is the first use of a SUTRA-ICE multi-dimensional flow and transport type of code to simulate meltwater retention and unsaturated and saturated flow in a firn aquifer system. This type of code is expected to be widely applicable to firn aquifer simulations in the future, because it represents an improvement in modeling multi-dimensional meltwater flow through unsaturated and saturated firn. This successful use of SUTRA-ICE indicates that this code and other similar codes can be more broadly applied to future studies of firn aquifers or meltwater flow through snow.

The results of modeling analyses indicate that the following factors are important controls on the simulated aquifer: (1) surface temperature, (2) meltwater recharge rate, (3) residual total-water saturation (minimum saturation of liquid plus ice) and (4) thickness of the capillary fringe (only if it extends to the snow surface). Firn temperatures are not sensitive to the ‘backbone’ fraction of ice (the amount assumed to never melt in the simulation for the temperature range considered), nor to the liquid saturation range over which the relative permeability drops from its maximum to minimum value, nor to the minimum relative permeability value.

SUTRA-ICE simulation results indicate that the basic conceptual model of the physics of firn aquifer formation and function that was developed on the basis of field data is consistent with the fundamental physics of groundwater flow and with the thermodynamics of freezing and thawing as these occur within an aquifer consisting entirely of water in its liquid and solid states. Differences between simulated steady-state liquid water levels and observed liquid water levels may indicate that the Helheim Glacier firn aquifer is not at steady state for its current recharge rates. Should the aquifer attain steady state in the future, or if recharge increases under a future warmer climate, the water table will intersect the snow surface. This would generate lakes and/or streams co-located with the firn aquifer, representing a fundamental shift in ice-sheet hydrologic facies.

Acknowledgements

Olivia Miller was supported by NSF grant number PLR-1417987 as she completed her PhD research at the University of Utah. D.K.S., R.F. and C.M. were supported by NSF grant number PLR-1417987. N.S. and L.M. were supported by NSF grant number PLR-1417993. C.M. was supported by NSF Grant PLR-1604058. Any use of trade, firm or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Author contributions

O.M. and C.V. designed model experiments, conducted modeling work and wrote most of the paper. D.K.S., C.M., R.F. and NS designed field experiments and contributed to model design and writing. L.M. provided seismic data and figures and helped with writing.

Footnotes

*

Now at U.S. Geological Survey, Utah Water Science Center, Salt Lake City, Utah, USA

References

Alley, RB, Dupont, TK, Parizek, BR and Anandakrishnan, S (2005) Access of surface meltwater to beds of sub-freezing glaciers: preliminary insights. Annals of Glaciology 40, 814. doi: 10.3189/172756405781813483CrossRefGoogle Scholar
Armstrong, RL and Brun, E (Eds.) (2008) Snow and Climate: Physical Processes, Surface Energy Exchange and Modeling. Cambridge: Cambridge University Press.Google Scholar
Briggs, MA and 5 others (2014) New permafrost is forming around shrinking Arctic lakes, but will it last? Geophysical Research Letters 41(5), 15851592. doi: 10.1002/2014GL059251CrossRefGoogle Scholar
Cazenave, A (2006) How fast are the ice sheets melting? Science 314(5803), 12501252. doi: 10.1126/science.1133325CrossRefGoogle ScholarPubMed
Chen, C, Howat, IM and De La Pena, S (2017) Formation and development of supraglacial lakes in the percolation zone of the Greenland ice sheet. Journal of Glaciology 63(241), 847853. doi: 10.1017/jog.2017.50CrossRefGoogle Scholar
Das, SB and 6 others (2008) Fracture propagation to the base of the Greenland ice sheet during supraglacial lake drainage. Science 320(5877), 778781. doi: 10.1126/science.1153360CrossRefGoogle Scholar
Echelmeyer, K, Clarke, TS and Harrison, WD (1991) Surficial glaciology of Jakobshavns Isbrae, West Greenland: part I. Surface morphology. Journal of Glaciology 37(127), 368382. doi: 10.1017/S0022143000005803CrossRefGoogle Scholar
Enderlin, EM and 5 others (2014) An improved mass budget for the Greenland ice sheet. Geophysical Research Letters 41(3), 866872. doi: 10.1002/2013GL059010CrossRefGoogle Scholar
Ettema, J and 5 others (2010) Climate of the Greenland ice sheet using a high-resolution climate model – part 1: evaluation. The Cryosphere 4(4), 511527. doi: 10.5194/tc-4-511-2010CrossRefGoogle Scholar
Evans, SG and Ge, S (2017) Contrasting hydrogeologic responses to warming in permafrost and seasonally frozen ground hillslopes. Geophysical Research Letters 44, 111. doi: 10.1002/2016GL072009.Google Scholar
Evans, SG, Ge, S, Voss, CI and Molotch, NP (2018) The role of frozen soil in groundwater discharge predictions for warming alpine watersheds. Water Resources Research 54(3), 15991615. doi: 10.1002/2017WR022098CrossRefGoogle Scholar
Evans, SG, Godsey, SE, Rushlow, CR and Voss, C (2020) Water tracks enhance water flow above permafrost in upland Arctic Alaska hillslopes. Journal of Geophysical Research: Earth Surface 125(2), 118. doi: 10.1029/2019JF005256Google Scholar
Fettweis, X (2007) Reconstruction of the 1979-2006 Greenland ice sheet surface mass balance using the regional climate model MAR. The Cryosphere 1(1), 2140. doi: 10.5194/tc-1-21-2007CrossRefGoogle Scholar
Forster, RR and 12 others (2014) Extensive liquid meltwater storage in firn within the Greenland ice sheet. Nature Geoscience 7(2), 14. doi: 10.1038/ngeo2043CrossRefGoogle Scholar
Gallée, H and Schayes, G (1994) Development of a three-dimensional meso-γ primitive equation model: Katabatic winds simulation in the area of Terra Nova Bay, Antarctica. Monthly Weather Review 122(4), 671685. doi: 10.1175/1520-0493(1994)122<0671:DOATDM>2.0.CO;22.0.CO;2>CrossRefGoogle Scholar
Ge, S, McKenzie, J, Voss, C and Wu, Q (2011) Exchange of groundwater and surface-water mediated by permafrost response to seasonal and long term air temperature variation. Geophysical Research Letters 38(14), 16. doi: 10.1029/2011GL047911.CrossRefGoogle Scholar
Grenier, C and 27 others (2018) Groundwater flow and heat transport for systems undergoing freeze-thaw: intercomparison of numerical simulators for 2D test cases. Advances in Water Resources 114(February), 196218. doi: 10.1016/j.advwatres.2018.02.001CrossRefGoogle Scholar
Gudmundsson, GH (2003) Transmission of basal variability to a glacier surface. Journal of Geophysical Research: Solid Earth 108(B5), 119. doi: 10.1029/2002jb002107CrossRefGoogle Scholar
Helm, V, Humbert, A and Miller, H (2014) Elevation and elevation change of Greenland and Antarctica derived from CryoSat-2. The Cryosphere 8(4), 15391559. doi: 10.5194/tc-8-1539-2014CrossRefGoogle Scholar
Jame, Y-W (1977) Heat and Mass Transfer in Freezing Soils (Ph.D. dissertation). University of Saskatchewan. Available at https://harvest.usask.ca/handle/10388/etd-11282008-091133.Google Scholar
Joughin, I, Tulaczyk, S, Fahnestock, M and Kwok, R (1996) A mini-surge on the Ryder Glacier, Greenland, observed by satellite radar interferometry. Science 274(5285), 228230. doi: 10.1126/science.274.5285.228CrossRefGoogle Scholar
Killingbeck, SF and 14 others (2020) Integrated borehole, radar, and seismic velocity analysis reveals dynamic spatial variations within a firn aquifer in southeast Greenland. Geophysical Research Letters 47(18), 110. doi: 10.1029/2020GL089335.CrossRefGoogle Scholar
Koenig, L, Miège, C, Forster, RR and Brucker, L (2014) Initial in situ measurements of perennial meltwater storage in the Greenland firn aquifer. Geophysical Research Letters 41(1), 8185. doi: 10.1002/2013GL058083CrossRefGoogle Scholar
Koenig, LS and 11 others (2015) Wintertime storage of water in buried supraglacial lakes across the Greenland ice sheet. The Cryosphere 9(4), 13331342. doi: 10.5194/tc-9-1333-2015CrossRefGoogle Scholar
Kozlowski, T (2007) A semi-empirical model for phase composition of water in clay-water systems. Cold Regions Science and Technology 49(3), 226236.CrossRefGoogle Scholar
Kuipers Munneke, P, Ligtenberg, SRM, van den Broeke, MR, van Angelen, JH and Forster, RR (2014) Explaining the presence of perennial liquid water bodies in the firn of the Greenland ice sheet. Geophysical Research Letters 41(2), 476483. doi: 10.1002/2013GL058389CrossRefGoogle Scholar
Kurylyk, BL and Watanabe, K (2013) The mathematical representation of freezing and thawing processes in variably-saturated, non-deformable soils. Advances in Water Resources 60, 160177. doi: 10.1016/j.advwatres.2013.07.016CrossRefGoogle Scholar
Kurylyk, BL, MacQuarrie, KTB and Voss, CI (2014) Climate change impacts on the temperature and magnitude of groundwater discharge from shallow, unconfined aquifers. Water Resources Research 50(4), 32533274. doi: 10.1002/2013WR014588CrossRefGoogle Scholar
Kurylyk, BL, Hayashi, M, Quinton, WL, McKenzie, JM and Voss, CI (2016) Influence of vertical and lateral heat transfer on permafrost thaw, peatland landscape transition, and groundwater flow. Water Resources Research 52(2), 12861305. doi: 10.1002/2015WR018057CrossRefGoogle Scholar
Lamontagne-Hallé, P, McKenzie, JM, Kurylyk, BL and Zipper, SC (2018) Changing groundwater discharge dynamics in permafrost regions. Environmental Research Letters 13(8), 111. doi: 10.1088/1748-9326/aad404.CrossRefGoogle Scholar
Langen, PL and 13 others (2015) Quantifying energy and mass fluxes controlling Godthåbsfjord freshwater input in a 5-km simulation (1991-2012). Journal of Climate 28(9), 36943713. doi: 10.1175/JCLI-D-14-00271.1CrossRefGoogle Scholar
Langen, PL, Fausto, RS, Vandecrux, B, Mottram, RH and Box, JE (2017) Liquid water flow and retention on the Greenland ice sheet in the regional climate model HIRHAM5: local and large-scale impacts. Frontiers of Earth Science 4, 110. doi: 10.3389/feart.2016.00110Google Scholar
Le Bars, D (2017) Earth's future uncertainty in sea level rise projections due to the dependence between contributors. Earth's Future 6, 12751291. doi: 10.1029/2018EF000849CrossRefGoogle Scholar
Legchenko, A and 9 others (2018 a) Estimating water volume stored in the south-eastern Greenland firn aquifer using magnetic-resonance soundings. The Journal of Applied Geophysics 150, 1120. doi: 10.1016/j.jappgeo.2018.01.005CrossRefGoogle Scholar
Legchenko, A and 9 others (2018 b) Investigating a firn aquifer near Helheim Glacier (South-Eastern Greenland) with magnetic resonance soundings and ground-penetrating radar. Near Surface Geophysics 16(4), 411422. doi: 10.1002/nsg.12001CrossRefGoogle Scholar
Ligtenberg, SRM, Helsen, MM and Van Den Broeke, MR (2011) An improved semi-empirical model for the densification of Antarctic firn. The Cryosphere 5, 809819. doi: 10.5194/tc-5-809-2011CrossRefGoogle Scholar
MacFerrin, M and 13 others (2019) Rapid expansion of Greenland's low-permeability ice slabs. Nature 573(7774), 403407. doi: 10.1038/s41586-019-1550-3CrossRefGoogle ScholarPubMed
Marchenko, S and 6 others (2017) Parameterizing deep water percolation improves subsurface temperature simulations by a multilayer firn model. Frontiers of Earth Science 5, 16. doi: 10.3389/feart.2017.00016Google Scholar
McKenzie, JM and Voss, CI (2013) Permafrost thaw in a nested groundwater-flow system. Hydrogeology Journal 21(1), 299316. doi: 10.1007/s10040-012-0942-3CrossRefGoogle Scholar
McKenzie, JM, Siegel, DI, Rosenberry, DO, Glaser, PH and Voss, CI (2007 a) Heat transport in the Red Lake Bog, Glacial Lake Agassiz Peatlands. Hydrological Processes 21(3), 369378. doi: 10.1002/hyp.6239CrossRefGoogle Scholar
McKenzie, JM, Voss, CI and Siegel, DI (2007 b) Groundwater flow with energy transport and water-ice phase change: numerical simulations, benchmarks, and application to freezing in peat bogs. Advances in Water Resources 30(4), 966983. doi: 10.1016/j.advwatres.2006.08.008CrossRefGoogle Scholar
McNerney, L (2016) Constraining the Greenland Firn Aquifer's Ability to Hydrofracture a Crevasse to the Bed of the Ice Sheet (thesis). University of Utah. Available at https://collections.lib.utah.edu/details?id=197636.Google Scholar
Meyer, CR and Hewitt, IJ (2017) A continuum model for meltwater flow through compacting snow. The Cryosphere 11(6), 27992813. doi: 10.5194/tc-11-2799-2017CrossRefGoogle Scholar
Miège, C and 12 others (2016) Spatial extent and temporal variability of Greenland firn aquifers detected by ground and airborne radars. Journal of Geophysical Research. Earth Surface 121(12), 23812398. doi: 10.1002/2016JF003869CrossRefGoogle Scholar
Miller, OL and 9 others (2017) Hydraulic conductivity of a firn aquifer in southeast Greenland. Frontiers of Earth Science 5, 38. doi: 10.3389/feart.2017.00038CrossRefGoogle Scholar
Miller, O and 7 others (2018) Direct evidence of meltwater flow within a firn aquifer in southeast Greenland. Geophysical Research Letters 45(1), 207215. doi: 10.1002/2017GL075707CrossRefGoogle Scholar
Miller, O and 10 others (2020) Hydrology of a perennial firn aquifer in Southeast Greenland: an overview driven by field data. Water Resources Research 56(8), 123. doi: 10.1029/2019wr026348.CrossRefGoogle Scholar
Montgomery, LN and 9 others (2017) Investigation of firn aquifer structure in southeastern Greenland using active source seismology. Frontiers of Earth Science 5, 10. doi: 10.3389/feart.2017.00010Google Scholar
Montgomery, L and 8 others (2020) Hydrologic properties of a highly permeable firn aquifer in the Wilkins Ice Shelf, Antarctica. Geophysical Research Letters 47(22), 110. doi: 10.1029/2020GL089552.CrossRefGoogle Scholar
Noël, B and 5 others (2015) Evaluation of the updated regional climate model RACMO2.3: summer snowfall impact on the Greenland Ice Sheet. The Cryosphere 9(5), 18311844. doi: 10.5194/tc-9-1831-2015CrossRefGoogle Scholar
Poinar, K and 5 others (2017) Drainage of southeast Greenland firn aquifer water through crevasses to the bed. Frontiers of Earth Science 5, 5. doi: 10.3389/FEART.2017.00005Google Scholar
Poinar, K, Dow, CF and Andrews, LC (2019) Long-term support of an active subglacial hydrologic system in southeast Greenland by firn aquifers. Geophysical Research Letters 46(9), 47724781. doi: 10.1029/2019GL082786CrossRefGoogle Scholar
Reijmer, CH, Van Den Broeke, MR, Fettweis, X, Ettema, J and Stap, LB (2012) Refreezing on the Greenland ice sheet: a comparison of parameterizations. The Cryosphere 6(4), 743762. doi: 10.5194/tc-6-743-2012CrossRefGoogle Scholar
Reijmer, C, Kuipers Munneke, P and Smeets, P (2019) Helhein firn aquifer weather station data and melt rates, Greenland, 2014-2016. urn:node:ARCTIC. doi: 10.18739/A26D5PB4RCrossRefGoogle Scholar
Rey, DM and 5 others (2020) Wildfire-initiated talik development exceeds current thaw projections: observations and models from Alaska's continuous permafrost zone. Geophysical Research Letters 47(15), 111. doi: 10.1029/2020GL087565.CrossRefGoogle Scholar
Rühaak, W and 7 others (2015) Benchmarking numerical freeze/thaw models. Energy Procedia 76, 301–210. doi: 10.1016/j.egypro.2015.07.866CrossRefGoogle Scholar
Rushlow, CR, Sawyer, AH, Voss, CI and Godsey, SE (2020) The influence of snow cover, air temperature, and groundwater flow on the active-layer thermal regime of Arctic hillslopes drained by water tracks. Hydrogeology Journal 28(6), 20572069. doi: 10.1007/s10040-020-02166-2CrossRefGoogle Scholar
Selmes, N, Murray, T and James, TD (2011) Fast draining lakes on the Greenland Ice Sheet. Geophysical Research Letters 38(15), 15. doi: 10.1029/2011GL047872CrossRefGoogle Scholar
Sergienko, OV (2013) Glaciological twins: basally controlled subglacial and supraglacial lakes. Journal of Glaciology 59(213), 38. doi: 10.3189/2013jog12j040CrossRefGoogle Scholar
Simonsen, SB and 5 others (2013) Assessing a multilayered dynamic firn-compaction model for Greenland with ASIRAS radar measurements. Journal of Glaciology 59(215), 545548. doi: 10.3189/2013JoG12J158.CrossRefGoogle Scholar
Smith, LC and 15 others (2015) Efficient meltwater drainage through supraglacial streams and rivers on the southwest Greenland ice sheet. Proceedings of the National Academy of Sciences of the USA 112(4), 10011006. doi: 10.1073/pnas.1413024112CrossRefGoogle ScholarPubMed
Smith, LC and 22 others (2017) Direct measurements of meltwater runoff on the Greenland ice sheet surface. Proceedings of the National Academy of Sciences of the USA 114(50), E10622E10631. doi: 10.1073/pnas.1707743114CrossRefGoogle ScholarPubMed
Sørensen, LS and 7 others (2011) Mass balance of the Greenland ice sheet (2003–2008) from ICESat data – The impact of interpolation, sampling and firn density. The Cryosphere 5(1), 173186. doi: 10.5194/tc-5-173-2011CrossRefGoogle Scholar
Steger, CR, Reijmer, CH and van den Broeke, MR (2017 a) The modelled liquid water balance of the Greenland ice sheet. The Cryosphere 11, 132. doi: 10.5194/tc-2017-88.CrossRefGoogle Scholar
Steger, CR and 11 others (2017 b) Firn meltwater retention on the Greenland Ice Sheet: a model comparison. Frontiers of Earth Science 5, 3. doi: 10.3389/feart.2017.00003Google Scholar
Stevens, CM and 6 others (2020) The community firn model (CFM) v1.0. Geoscientific Model Development 13(9), 43554377. doi: 10.5194/gmd-13-4355-2020CrossRefGoogle Scholar
Sundal, AV and 5 others (2009) Evolution of supra-glacial lakes across the Greenland Ice Sheet. Remote Sensing of Environment 113(10), 21642171. doi: 10.1016/j.rse.2009.05.018CrossRefGoogle Scholar
Van Meijgaard, E, Van Ulft, LH, Bosveld, FC, Lenderink, G and Siebesma, AP (2008) The KNMI regional atmospheric climate model RACMO, version 2.1. Tech. report; TR – 302, 43.Google Scholar
Van Pelt, WJJ and 5 others (2012) Simulating melt, runoff and refreezing on Nordenskiöldbreen, Svalbard, using a coupled snow and energy balance model. The Cryosphere 6(3), 641659. doi: 10.5194/tc-6-641-2012CrossRefGoogle Scholar
Vandecrux, B and 10 others (2018) Drivers of firn density on the Greenland ice sheet revealed by weather station observations and modeling. Journal of Geophysical Research. Earth Surface 123(10), 25632576. doi: 10.1029/2017JF004597CrossRefGoogle Scholar
Vandecrux, B and 12 others (2020 a) Firn cold content evolution at nine sites on the Greenland ice sheet between 1998 and 2017. Journal of Glaciology 66(258), 591602. doi: 10.1017/jog.2020.30CrossRefGoogle Scholar
Vandecrux, B and 22 others (2020 b) The firn meltwater Retention Model Intercomparison Project (RetMIP): evaluation of nine firn models at four weather station sites on the Greenland ice sheet. The Cryosphere 14(11), 37853810. doi: 10.5194/tc-14-3785-2020CrossRefGoogle Scholar
Verjans, V and 5 others (2019) Development of physically based liquid water schemes for Greenland firn-densification models. The Cryosphere 13(7), 18191842. doi: 10.5194/tc-13-1819-2019CrossRefGoogle Scholar
Voss, CI (2011) Editor's message: groundwater modeling fantasies-part 2, down to earth. Hydrogeology Journal 19(8), 14551458. doi: 10.1007/s10040-011-0790-6CrossRefGoogle Scholar
Voss, CI and Provost, AM (2002) (Version 2.2, September 22, 2010), SUTRA, a model for saturated-unsaturated variable density ground-water flow with energy or solute transport. US Geological Survey Water-Resources Investigations Report 2002-4231, 291 p.Google Scholar
Walvoord, MA, Voss, CI, Ebel, BA and Minsley, BJ (2019) Development of perennial thaw zones in boreal hillslopes enhances potential mobilization of permafrost carbon. Environmental Research Letters 14(1), 111. doi: 10.1088/1748-9326/aaf0cc.CrossRefGoogle Scholar
Watanabe, K and Wake, T (2009) Measurement of unfrozen water content and relative permittivity of frozen unsaturated soil using NMR and TDR. Cold Regions Science and Technology 59(1), 3441. doi: 10.1016/j.coldregions.2009.05.011CrossRefGoogle Scholar
Wellman, TP, Voss, CI and Walvoord, MA (2013) Impacts of climate, lake size, and supra- and sub-permafrost groundwater flow on lake-talik evolution, Yukon Flats, Alaska (USA). Hydrogeology Journal 21(1), 281298. doi: 10.1007/s10040-012-0941-4CrossRefGoogle Scholar
Wever, N and 5 others (2015) Verification of the multi-layer SNOWPACK model with different water transport schemes. The Cryosphere 9(6), 22712293. doi: 10.5194/tc-9-2271-2015CrossRefGoogle Scholar
Wever, N, Würzer, S, Fierz, C and Lehning, M (2016) Simulating ice layer formation under the presence of preferential flow in layered snowpacks. The Cryosphere 10(6), 27312744. doi: 10.5194/tc-10-2731-2016.CrossRefGoogle Scholar
Winter, TC, Harvey, JW, Lehn Frank, O and Alley, WM (1998) Ground water and surface water a single resource. U.S. Geological survey Circular 1139. doi: 10.3133/CIR1139CrossRefGoogle Scholar
Zhou, X, Zhou, J, Kinzelbach, W and Stauffer, F (2014) Simultaneous measurement of unfrozen water content and ice content in frozen soil using gamma ray attenuation and TDR. Water Resources Research 50(12), 96309655. doi: 10.1002/2014WR015640CrossRefGoogle Scholar
Zipper, SC, Lamontagne-Hallé, P, McKenzie, JM and Rocha, AV (2018) Groundwater controls on postfire permafrost thaw: water and energy balance effects. Journal of Geophysical Research. Earth Surface 123(10), 26772694. doi: 10.1029/2018JF004611CrossRefGoogle Scholar
Zwally, HJ and 5 others (2002) Surface melt-induced acceleration of Greenland ice-sheet flow. Science 297(5579), 218222.CrossRefGoogle ScholarPubMed
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Fig. 1. (a) Firn aquifer site map in southeastern Greenland and conceptual model of hydrology adapted from Miller and others (2020). Landsat 8 composite image of Helheim Glacier (21 August 2014) showing profile simulated and conceptual model applied in simulations in 1-D and 2-D. Elevation contours from Cryosat-2 DEM (Helm and others, 2014). (b) Firn aquifer geometry along simulated profile determined from mean 1-D velocity profiles (red line) obtained from seismic (solid black line, inversion of travel times) and radar (water table, upper dashed black line) surveys over a 15 km profile. Aquifer base was dertermined by probability of seismic veloicty increase (lower dashed black line); details are presented in Montgomery and others (2017). Simulated profile extends upslope beyond the seismic profile.

Figure 1

Fig. 2. Two-dimensional cross-sectional model setup and boundary conditions. Top is located at upper surface of snow (‘ground’ surface), bottom is located at approximate depth where firn temperature is −1°C and liquid water has frozen into solid ice except irreducible liquid saturation with no connected porosity. Downhill boundary is located at a crevasse in which the water table is set at 20 m depth, and uphill boundary is located near upper extent of the observed firn aquifer. Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.

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Table 1. Table showing general model specifications, boundary conditions and physical parameters used in 1-D and 2-D simulations

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Table 2. Table showing model inputs and parameters for 1-D sensitivity analysis and simulations

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Table 3. Table showing backbone and user-defined function values used in 2-D simulations

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Fig. 3. Simulated and measured firn temperature. (a) Simulated firn temperature from the icy, wet and dry base cases and icy case with winter surface temperature of −5°C. Dry and wet base case results overlay one another. (b) Simulated dry base case compared to measured firn temperature profile for a range of parameters that simulated firn temperature is insensitive to. All results overlay one another. (c) Simulated firn temperature from the dry base case with a range of winter surface temperature compared to measured firn temperature, (d) and simulated firn temperature from the dry base case with a range of residual total-water saturation (unsaturated function) values compared to measured firn temperature. Simulated firn temperature is most sensitive to winter surface temperature and the residual total-water saturation in the total-water saturation function.

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Fig. 4. Simulated fluid pressure and firn temperature for three recharge rates (5, 15 and 30 cm a−1). The water table occurs where the fluid pressure is zero (shown in blue-white boundary on the pressure plot). Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.

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Fig. 5. Simulated liquid saturation, ice saturation and total-water saturation (liquid plus ice) for three recharge rates (5, 15 and 30 cm a−1). Liquid and ice saturations are the volume of liquid and ice per volume of pore space, respectively. Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.

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Fig. 6. Simulated firn aquifer showing liquid saturation, specific discharge and logarithm of specific discharge, to visualize near-vertical flow through the unsaturated zone and lateral flow through the saturated zone for three recharge rates (5, 15 and 30 cm a−1). The region of transition from maximum to minimum liquid saturation around the aquifer is very narrow. Specific discharge is a product of fluid velocity, firn total porosity, and, liquid-water saturation, sometimes referred to as ‘Darcy velocity’. Snow surface gradient is 0.01 m m−1. Vertical exaggeration is 50 times.