3.1 Unsaturated flow formulation

This study explores using SP-field measurements to calculate meltwater percolation flux vertically downward within the snowpack under unsaturated flow conditions. The unsaturated flow formulation builds upon the study of Kulessa and others (Reference Kulessa, Chandler D, Revil and Essery2012), who extended SP theory to the problem of gravity-driven unsaturated flow in a vertical melting snow column. They derived an equation to describe the SP signal generated by the unsaturated flow percolating through the snowmelt column, which is shown below (Eqn (1)), with an added correction (personal communication from Kulessa, A. and Revil, A., 2020) to add the measurement length term (L) to the numerator:

(1)$$\psi _{\rm m} = \displaystyle{{\varepsilon \zeta } \over {\sigma _{\rm w}}}\displaystyle{{S_{\rm w}} \over {S_{\rm e}^n }}\displaystyle{L \over {kA}}Q$$

where ψ _m is the streaming potential between measurement and reference electrodes (V); ɛ is the meltwater dielectric permittivity (F m⁻¹) (constant 7.8 × 10⁻⁹ Farads per m (Kulessa and others, Reference Kulessa, Chandler D, Revil and Essery2012)); ζ is the zeta potential (V); σ _w is the meltwater electrical conductivity (S m⁻¹); S _w is the water saturation (=LWC/porosity); S _e is the effective water saturation; n is the pore size parameter; k is the intrinsic permeability (m²); A is the column cross-sectional area; Q is the volumetric flow rate (m³ d⁻¹) and L is the distance between reference and measurement electrodes (m).

Kulessa and others (Reference Kulessa, Chandler D, Revil and Essery2012) verified Eqn (1) by using it to model SP signals and comparing the results to a laboratory snowmelt column experiment. Eqn (1) shows that the relationship between streaming potential (ψ _m) and the fluid flow rate is affected by a significant number of variables that will have to be measured or estimated in the field to determine flow rate from SP data. To solve this problem, the methods included the use of an in-field snowmelt column test to estimate certainty of the parameters in Eqn (1) which were then applied to calculate percolation fluxes within the snowpack. We will assume that thermoelectric and electrochemical potentials are zero, and the appropriateness of these assumptions is addressed in subsequent sections.

We can calculate the meltwater flux, or Darcy velocity, as a function of the streaming potential and other parameters, by rearranging Eqn (1), as follows:

(2)$$q_{{\rm sp}} = \displaystyle{{\psi _{\rm m}/L} \over {( \varepsilon \zeta /\sigma _{\rm w}) ( S_{\rm w}/kS_{\rm e}^n ) }}$$

where q _sp = Q/A (m d⁻¹).

The SP-modeled meltwater Darcy velocity, or flux (q _sp), has units of mm d⁻¹ w.e., although for brevity we will omit the term w.e. and report q _sp as mm d⁻¹. For this study, we measured SP signals in mV, and report the electrical field strength (E, mV m⁻¹) measured across two electrodes of spacing, L (m):

(3)$$E = \psi _{\rm m}/L$$

We measured the SP electrical field strength directly between paired electrodes, without any distant isolated reference electrode. We refer to the electrical field strength hereinafter as SP-field strength or simply SP.

Following the unsaturated flow formulation used by Kulessa and others (Reference Kulessa, Chandler D, Revil and Essery2012), we use the Brooks and Corey (Reference Brooks and Corey1964) constitutive relationships, as follows:

(4)$$S_{\rm e} = \displaystyle{{( {S_{\rm w}-S_{\rm r}} ) } \over {( {1-S_{\rm r}} ) }}$$

(5)$$k_{\rm r} = S_{\rm e}^n $$

(6)$$S_{\rm e} = \left({\displaystyle{{H_{\rm o}} \over {H_{\rm c}}}} \right)^\lambda $$

where S _r is the residual water saturation, k _r is the relative permeability, H _c is the capillary pressure head, H _o is the air entry capillary head and n = (2 + 3λ)/λ.

In Eqns (4) and (5), the exponents n and λ are characteristic of the pore size distribution of the porous media that control the relationships between permeability, saturation and capillary pressure. Pore size distribution also controls snow permeability (k, m²) which we estimated from density and grain size (Colbeck and Anderson, Reference Colbeck and Anderson1982; Kulessa and others, Reference Kulessa, Chandler D, Revil and Essery2012) using the following, from Shimizu (Reference Shimizu1970):

(7)$$k = 0.077d^2{\rm e}^{{-}0.0078\rho _{\rm s}}$$

where d is the mean snow grain diameter (m) and ρ _s is the snow density (kg m⁻³).

3.2 Field study location

A number of students from the Juneau Icefield Research Program (JIRP) and myself undertook this field feasibility study during two separate short summer field sessions, each ~1 week in duration, in 2018 and 2019. We conducted the field study at the Matthes-Llewellyn glacier divide (Fig. 1), ~5 km north of the border between Alaska, USA, and British Columbia, Canada. The site is located at a transition between a predominately maritime climate to the south and west and a predominately continental climate to the north and east. The Juneau Icefield is a temperate glacier system, and during the summer melt season the glacier system is isothermal, with snow and ice temperatures at 0°C throughout. The elevation at the study site is ~1850 m, and since the location is a glacier divide the surface slope is essentially flat. JIRP conducted ice-penetrating radar studies during 2018 and 2019 that indicated the glacier thickness was ~900 m at the site. Nearby glacier mass-balance study pits in 2018 and 2019 indicated that the late July depth of the seasonal snow layer ranged from ~3–4 m. Matthes Glacier flows south as part of the Taku Glacier system, which was the subject of a glacier mass-balance reanalysis study (McNeil and others, Reference McNeil2020) that further describes the climatological and glaciological setting of the Juneau Icefield.

Fig. 1. Juneau Icefield study site location map. Source: Esri, Maxar, GeoEye, Earthstar Geographics, CNES/Airbus DS, USDA, USGS, AeroGRID, IGN and the GIS User Community.

3.3 Weather and energy-balance measurements

We measured weather and energy balance to characterize conditions during the fieldwork that would drive snowmelt and meltwater percolation. Energy-balance data served as a basis calculated expected melt for comparison to SP-modeled percolation fluxes, as described in Section 3.7. A temporary meteorological station was co-located with the snowmelt percolation study which measured wind speed and direction, temperature, relative humidity, as well as four components of surface energy balance including longwave (LW) and shortwave (SW) radiation inputs and outputs. We installed a visually read ablation stake to monitor actual loss of surface snow, consisting of an aluminum avalanche probe with 0.5 cm markings. Table 1 summarizes the meteorological station measurement equipment specifications. A Campbell Scientific CR-10x data logger with 12 V solar power supply, housed in a waterproof Pelican™ case logged all data acquisition at 15 s intervals with 20 samples averaged over each recorded 5-min data period.

Table 1. Sensors used in the meteorological station

The balance of energy (Q, W m⁻²) at the snow surface drives snowmelt. This includes LW and SW radiation inputs and outputs as well as energy associated with air temperature, evaporation/condensation and precipitation (Hock, Reference Hock2005), as follows:

(8)$$Q_{\rm N} + Q_{\rm H} + Q_{\rm L} + Q_{\rm G} + Q_{\rm R} + Q_{\rm M} = 0$$

where Q _N is the net radiation energy flux (solar); Q _H is the sensible heat energy flux (temperature); Q _L is the latent heat energy flux (evaporation/sublimation/condensation); Q _G is the ground heat energy flux (geothermal); Q _R is the rain heat energy flux (precipitation) and Q _M is the energy consumed by melt.

We can neglect ground heat energy flux, based on the isothermal glacier characteristics. Sensible and latent heat energy fluxes are categorized as turbulent energy fluxes because they rely on near-surface atmospheric turbulence for energy transfer between the snow surface and the atmosphere. Turbulent energy fluxes are generally less than net radiation over long time periods, but are significant contributors to short-term transient variation in melting (Hock, Reference Hock2005). Turbulent energy fluxes are challenging to estimate using bulk methods, because of uncertainty in using a transfer coefficient to represent turbulence profiles that are spatially and temporally variable (Hock, Reference Hock2005). Nonetheless, to support a more complete estimate of expected transient meltwater percolation flux based on surface energy balance, we estimated Q _H according to the methods used in the factorial snow model (Essery, Reference Essery2015), as follows:

(9)$$Q_{\rm H} = \rho _{\rm a}c_pC_{\rm H}U_{\rm a}( {T_{\rm s}-T_{\rm a}} ) $$

where ρ _a is the air density; c_p is the heat capacity of air = 1005 J K⁻¹ Kg⁻¹; C _H is the dimensionless transfer coefficient; U _a is the wind speed at measurement height z; T _s is the surface temperature and T _a is the air temperature at measurement height z; and where

(10)$$C_{\rm H} = f_{\rm H}k^2\left[{\ln \displaystyle{{z_{\rm U}} \over {z_0}}\;{\rm ln}\displaystyle{{z_{{\rm TQ}}} \over {z_{{\rm oh}}}}} \right]^{{-}1}$$

where f _H is the atmospheric stability function ( = 1.0); k is the von Karman constant ( = 0.4); z _U = z_TQ is the measurement height for wind speed and humidity; z ₀ is the surface momentum roughness length and z _oh = 0.1z ₀.

The measurement height for wind and humidity at the meteorological station was 1.0 m. Surface momentum roughness length for snow surfaces can vary over a wide range of values, from 0.004 to 70 mm (Hock, Reference Hock2005). We use values of surface momentum roughness of z ₀ of 10^−4.6 m for latent heat transfer and 10⁻⁶ m for sensible heat transfer, taken from an eddy covariance study at a mountain glacier in western Canada by Fitzpatrick and others (Reference Fitzpatrick, Radić and Menounos2017).

Following Essery (Reference Essery2015), latent heat flux was determined as follows:

(11)$$Q_{\rm L} = L_{\rm e}S$$

where L _e is the latent heat of evaporation/condensation = 2.835 × 10⁶ J kg⁻¹ and S is the mass rate of vapor transfer (kg m⁻² S⁻¹), and where

(12)$$S = \rho _{\rm a}C_{\rm H}U_{\rm a}[ {Q_{{\rm sat}}-Q_{\rm a}} ] $$

where Q _sat is the specific humidity at water vapor saturation, at melting snow surface and Q _a is the specific humidity of air at measurement height.

We used Eqns (8) through (12) and field meteorological measurements to calculate expected melt rate (M, in m w.e. s⁻¹) (Eqn (13)) (Hock, Reference Hock2005). In conventional units, Eqn (13) reduces to: Q _M (W m⁻²) × 0.26 = M (mm w.e. d⁻¹):

(13)$$M = \displaystyle{{Q_{\rm M}} \over {\rho _{\rm w}L_{\rm f}}}$$

where ρ _w is the density of water (kg m⁻¹) and L _f is the latent heat of fusion = 334 000 J kg⁻¹.

3.4 Water retention curve measurement

We measured water retention curves relating capillary pressure and water saturation as a baseline metric of unsaturated hydraulic characteristics of the seasonal snowpack, using a sample from Taku Glacier on 21 July 2018, and a sample from the Matthes-Llewellyn divide on 25 July 2018. The testing apparatus (Clayton, Reference Clayton2017) involved an 8 cm diameter isothermal test cell to maintain the snow core sample at 0°C, which prevented melting during the drainage experiment. Fitting the capillary pressure–saturation curves in Eqn (6) determined the Brooks and Corey (Reference Brooks and Corey1964) pore size distribution parameters λ, n = (2 + 3λ)/λ, S _r, and H _o. Section 4.2.2 addresses uncertainty in parameters determined from the water retention curve measurements, in the context of snowmelt column test results.

3.5 Snowmelt column tests

We conducted snowmelt column tests in the field during both the 2018 and 2019 field sessions, to calibrate the SP measurements and determine values of zeta potential and n for application to Eqn (2) in evaluating in situ measurements. The snowmelt column consisted of a 0.6 m long schedule 40 PVC pipe with an inside diameter of 0.15 m, and with a beveled end to facilitate coring into the snowpack. We inserted the column vertically through the upper 0.6 m of the snowpack and subsequently excavated and removed it for testing. A sealed hot water reservoir placed at the top of the column induced controlled melting. An insulating cover and shading minimized annular column melting from ambient conditions. A tipping-bucket rain gage on the meteorological station measured the meltwater volume exiting the base of the column (Fig. 2). SP and TDR sensors in the lower half of the column measured ψ _m, expressed as SP electrical field strength (E), and S _w during meltwater percolation. We inserted 10 cm long SP electrodes through holes in the column spaced 0.2 m vertically with the reference (−) voltage electrode on top, and the (+) electrode placed 10 cm above the base of the column. A TDR waveguide was centered in between the electrodes. Section 3.6 describes the specifications of the SP and TDR sensors. We also used a Hanna Instruments model 98129 tester to measure σ _w and pH in the column effluent water. These data were not temperature compensated, and we performed daily in-field 2-point instrument calibrations.

Fig. 2. Snowmelt column test setup. The PVC column was fitted with SP and TDR sensors, and was placed over the tipping bucket rain gage on the meteorological station. A sealed hot water reservoir was placed at the top of the column to drive controlled melting. The column is shaded and wrapped in an insulating cover to minimize annular column melting from ambient conditions. Photo credit: Andrew Opila.

The column tests allowed an empirical comparison of observed meltwater effluent from the column to meltwater flux within the column modeled using Eqn (2). We applied the measured E and S _w data to Eqn (2) to develop a best fit of SP-modeled q _sp vs observed meltwater effluent from the column. This allowed the determination of an expected value of zeta potential and an evaluation of the sensitivity of the Brooks and Corey pore size parameter, n. We evaluated several values of n using Eqn (2) for each column test, in order to assess the sensitivity of this parameter to calculate transient meltwater flux. For each value of n evaluated, an expected value of zeta potential was then determined by calibrating measured flux to calculated flux, with a sum of residuals of zero over the test period.

The empirical approach adopted to evaluate the column test data involved applying a fixed value of zeta potential to solve Eqn (2) over the full duration of each column test, and subsequently to the in situ measurements. However, in reality zeta potential varies with changes in pH and σ _w (Revil and others, Reference Revil, Schwaeger, Cathles and Manhardt1999; Kulessa and others, Reference Kulessa, Chandler D, Revil and Essery2012). We measured these water quality parameters over time in meltwater eluted from the column tests. However, methods for the continuous sampling and measurement of these water quality parameters from pore water within the snowpack remain for future development. Therefore, without transient in situ measurement of pH and σ _w, the estimation of zeta potential is likely approximate. It is ultimately a limitation of this feasibility study that we are using zeta potential as a fitting parameter, and not directly measuring the electrochemical properties of the system. Therefore, the value of zeta potential determined may not be explicitly representative of the actual electrochemical properties of the system. This is an area for further research. Accordingly, we cannot resolve the potential errors associated with the estimation of zeta potential in this feasibility study, although Section 5.2 provides further discussion.

3.6 In situ snow sensors

We placed snow sensors horizontally into undisturbed snow through the vertical wall of a snow study pit for the measurement of SP and S _w. Sensors were pre-cooled to 0°C, and immediately after placement of the snow sensors, the snow study pit was backfilled with snow to maintain the 0°C isothermal system and prevent melt-out of the sensors. We inserted the SP electrodes to a distance of 1 m beyond the snow study pit sidewall. We placed TDR waveguides used for the measurement of S _w to a distance of ~0.2–0.3 m into undisturbed snow. This spatial alignment minimized the potential disruption of the flow field through undisturbed snow in the vicinity of the SP electrodes. However, since the SP and TDR data were not perfectly spatially coincident, spatial variability under meltwater percolation conditions could therefore contribute to errors when we combined the data into Eqn (2).

The SP electrodes consisted of 8-mm diameter round Ag–AgCl sintered biomedical electroencephalogram electrodes (BioMed Electrodes, model BME-8). The electrodes were embedded in epoxy, at a 45° angle, in the tip of a 9-mm diameter, 1.2 m long fiberglass wand (Figs 3, 4). We placed each SP electrode in the snow with the angled tip facing upward to maximize contact with downward percolating meltwater. In order to provide effective contact between the electrode and the snowpack, we placed a tension device at the snow study pit vertical wall, consisting of a bovine corkscrew trochar and elastic cord system (Fig. 4). This system placed mild forward pressure onto the electrode tip.

Fig. 3. 9-mm diameter SP electrodes fabricated using Ag–AgCl sintered biomedical electrodes embedded in epoxy at the tip of a fiberglass wand. White paint shows wear from snow insertion.

Fig. 4. Photo of in situ SP electrode wand, 1.2 m in length and with tip pressure device adapted from a bovine corkscrew trochar and elastic cord.

The placement of Ag–AgCl sintered electrodes directly into unsaturated porous media for SP measurements was described by Jougnot and Linde (Reference Jougnot and Linde2013). They found that electrode effects generating electrical potential would primarily be expected due to temperature variations, which are not present in the isothermal snowpack. Static testing of the electrodes in a no-flow snow meltwater bath resulted in stable measured electrical potential between the electrode pairs of <0.5 mV over a 48-h period.

In order to measure the electrical field strength (E) at specific locations, we wired the SP electrodes in vertically spaced pairs, with the high voltage (+) electrode of each pair oriented 20 cm physically below the reference (−) electrode. There was no isolated reference electrode. We used a bubble level to insert the electrodes horizontally into the snowpack to approximately maintain the desired spacing at the electrode tip. We placed a TDR waveguide centered vertically in between each electrode pair. We used the SP and TDR data to calculate the value of q _sp for each 5-min data logger time step using Eqn (2) and the parameters determined from the snowmelt column test.

Campbell Scientific Model CS655 TDR waveguides, which have two 120 mm long rods set at 32 mm spacing, provided measurements of S _w. Diaz and others (Reference Díaz, Muñoz, Lakhankar, Khanbilvardi and Romanov2017) previously used Campbell Scientific Model CS650 TDR waveguides to measure LWC in snow, which employs the same sensor technology and electronics. The TDR waveguide SDI-12 output signal reported the measurements of apparent dielectric permittivity (P), which we converted to S _w using an approximate function (Eqn (14)). Equation (14) is a purely empirical expression fitted to experimental data (Fig. 5) collected by placing a CS655 TDR waveguide into a 0.15 m long × 0.15 m diameter test cell. The calibration experiment involved measuring P while applying known changes in water saturation to the test cell under both drainage and imbibition conditions. We used Eqn (14) to process field TDR data collected during both the 2018 and 2019 field seasons:

(14)$$S_{\rm w} = \displaystyle{{( \;C_1^P /C_2-\;1\;) /100 + 0.0012} \over \Phi }$$

where C ₁ = 8, C ₂ = 9 and Φ is the porosity.

Fig. 5. Measurements of apparent dielectric permittivity produced using the CS655 TDR waveguides under controlled drainage and imbibition conditions of known water saturation (S _w). Empirical function Eqn (14) determined by visual fit to data.

3.7 Error analysis approach

This study involved determination of the Darcy velocity of unsaturated meltwater percolation flux, by solving Eqn (2) using measured SP electrical field strength (E) and S _w data. Thompson and others (Reference Thompson, Kulessa, Essery and Lüthi2016) evaluated sources of error in the various parameters in Eqn (1). They noted that there is great difficulty in estimating the actual measurement uncertainty of individual variables, and therefore they considered hypothetical uncertainty ranges in these parameters within their error analysis. Due to the difficulty in determining individual measurement uncertainties, we have undertaken an empirical error analysis consisting of two parts. The percent difference (PD) was determined between the cumulative SP-modeled percolation flux over time (in mm w.e.) using Eqn 2, and (a) ablation measurements of snow loss using a snow stake, and (b) calculations of cumulative expected melt (M) using the surface energy-balance measurements. Measured precipitation was added to the above.