2.1 Subglacial channel generator

The subglacial channel generator is a statistics- and physics-based tool that creates a channel network embedded in a 2-D distributed system (Irarrazaval and others, Reference Irarrazaval2019). It depends on seven parameters whose values will be inferred in our inversion procedure. The subglacial channel generator presented in this study incorporates two novelties: (1) channel location variability is incorporated by extending the parametrization and adding a geostatistical parameter. (2) The flotation factor f in Shreve's equation (Shreve, Reference Shreve1972) is incorporated to add more variability to the channel networks.

Note that the subglacial channel generator produces a set of channel networks embedded in a distributed system. Water pressure and flow speed in the subglacial systems is then computed by a separate model via flow equations and recharge forcing (Section 2.2).

The subglacial systems are set up in a 2-D domain considering pressurized water flow, where water follows the hydraulic potential defined by

(1)$$\phi = \phi _z + p_{\rm w}.$$

Here p _w is the water pressure and the ϕ _z = ρ _wgB is the elevation potential with water density ρ _w, acceleration of gravity g and bedrock elevation B(x,y).

The first step is to generate the channel network topology or channel architecture. Similar to previous studies based on routing algorithms (e.g., Arnold and others, Reference Arnold, Richards, Willis and Sharp1998; Chu and others, Reference Chu, Creyts and Bell2016), Shreve's approximation to the hydraulic potential (Shreve, Reference Shreve1972) is obtained by setting p _w = fp _i in Eqn (1). Where p _i = ρ _igH is the ice overburden pressure considering an ice density ρ _i and ice thickness H(x,y). The flotation factor f is usually set to 1 but values ranging from 0.6 to 1.1 have been employed previously (e.g., Chu and others, Reference Chu, Creyts and Bell2016). Here, we include a nonuniform noise or perturbation field ϕ _R(x, y) which is added to Shreve's hydraulic potential to obtain an approximated hydraulic potential field ϕ*,

(2)$$\phi ^\ast{ = } \rho _{\rm w}gB + f\rho _{\rm i}gH + \phi _{\rm R}.$$

The role of ϕ _R is key in determining channel location. Flow routing can be highly sensitive to small variations in the potential surface and a small perturbation could induce large downstream deviations of hydraulic paths. In this study, ϕ _R is modelled as a Gaussian random field (GRF). The GRF is a spatially correlated random field generated from random white noise and parametrized in terms of its variance and integral scales. This is useful, as varying the variance, integral scales and modifying the white noise allows for perturbations of different magnitude, correlation in space and location, which influence the channel topology. However, one of the challenges is to gradually modify the white noise to provide a continuous transition between channel networks. To overcome this issue, we create a larger GRF from which we crop ϕ _R by varying the shift s of the cropping-region along the y dimension (Fig. 1). Tests showed that the overall channel location probability is not affected by the dimension along which s is varied. This is expected as the GRF is isotropic and large enough to accommodate several independent cropping-regions or realization of ϕ _R. The inclusion of s allows for a smoother deformation of the network, useful when exploring the model space (see in Supplementary material: Subglacial channel generator video 1). As an analogy, the variance, integral scales and shift can be seen as changing the amplitude, wavelength and phase shift of a periodic wave, which results in a simple parametrization of the GRF. Note that Irarrazaval and others (Reference Irarrazaval2019) found that a sufficient channel network variability can be achieved with a fixed GRF variance. Here we chose a GRF variance of 0.0058 (MPa)² equivalent to a standard deviation of ~7.7 m water column. The selected value is similar to the small-scale variations of ϕ, such that it influences ϕ* but does not disrupt the large-scale trend. Then, the subglacial channel generator considers three parameters that modify ϕ*: flotation factor f, integral scales l_xy and shift s, hereafter referred to as the structural parameters of the subglacial channel generator.

Fig. 1.

Synthetic example of subglacial channel generator (water flow from right- to left-hand side). On the right-hand side colour fields correspond to the GRF (ϕ _R), and on the left-hand side to unconditioned subglacial channels. The influence of the shift s parameter is shown in (a), (b) and (c), by shifting the GRF (f and l_xy are fixed) and computing the channels. (a) and (b) show minor differences when the shift is small. (c) shows different structures as it considers a completely different part of the GRF. In (d), shift is the same as in (c), but the integral scale (l_xy) of the GRF is smaller.

Once the hydraulic potential is obtained, the D8 flow routing algorithm (O'Callaghan and Mark, Reference O'Callaghan and Mark1984) is computed over the hydraulic potential ϕ* and the upstream contribution flow accumulation is computed for each cell. In this step, the spatial variations in water recharge (i.e., moulins and water recharge by tributary glaciers) are considered to compute the upstream flow contribution. The flow paths with an accumulation higher than threshold parameter c correspond to the channel network. Parameter c is set to ensure that all moulins are connected to the subglacial channels. Flow routing and channel structure are computed using TopoToolbox 2 (Schwanghart and Kuhn, Reference Schwanghart and Kuhn2010; Schwanghart and Scherler, Reference Schwanghart and Scherler2014).

The last step is to assign radii to each of the channel network segments r _i. This is done computing the Shreve's stream order u _i (Shreve, Reference Shreve1966) and transforming it to a radius using the following equation (Borghi and others, Reference Borghi, Renard and Cornaton2016),

(3)$$r\lpar {u_i} \rpar = a{\rm e}^{u_ib}\comma \;$$

where a and b are parameters determined in the inversion procedure. Then, the channel network is embedded into the distributed system modelled as a homogeneous 2-D layer with transmissivity T _d. Lastly, in order to model dye-tracer transit speeds, we account for the moulins' inflow modulation time. Inflow modulation time corresponds to the time water spends in the englacial drainage system until it reaches the subglacial channels. Moreover, inflow modulation time, which has been shown to significantly affect the overall tracer transit times (e.g., Werder and others, Reference Werder, Schuler and Funk2010), could be estimated if the recharge hydrograph, subglacial water pressure and moulin geometry are available. As these data are unavailable for the study site, we include parameter τ_i which accounts for the inflow modulation time where the subscript i enumerates the moulins with tracer data.

In summary, the channel generator uses seven parameters. Parameters a and b determine the channel radii and T _d the transmissivity of the distributed system. The structural parameters l_xy, s and the flotation factor f control the channel location and/or network topology. The first two modify the GRF, whereas the flotation factor controls an overall trend on Shreve's equation. Finally, τ_i accounts for the inflow modulation time. All parameters are inferred in the inversion procedure.

2.2 Water flow model

A water flow model is used to compute water pressure p _w (Eqn (1)) and water discharge inside previously generated subglacial systems. Water flow is solved in steady-state conditions using the finite element GROUNDWATER code (Cornaton, Reference Cornaton2007) based on the framework presented in Irarrazaval and others (Reference Irarrazaval2019). The subglacial drainage system is modelled as two coupled components: distributed and channelized. Both components of the subglacial system are coupled using a finite-element mesh with shared nodes, assuming continuity of the pressure field. This allows water and mass exchanges between the distributed system and channels that are driven by the pressure gradient.

The distributed system is modelled as a 2-D layer, discretized in 25 m edge quadrangles and with homogeneous transmissivity T _d. Water mass is conserved assuming incompressibility and pressurized flow, then Darcy-laminar flow is considered under the assumptions of a nondeformable porous medium and vertically-integrated flow equations:

(4)$$q = {-}T_{\rm d}\nabla \phi \comma \;$$

with q the flux, T _d the transmissivity of the distributed system and $\nabla \phi$ the gradient of the hydraulic potential.

The channelized system is modelled as a network of 1-D cylindrical elements of radius r. Note that the radii are fixed as we are considering a snapshot model (no time derivatives). Discharge in the channel network is computed using the nonlinear Manning-Strickler empirical formulation for turbulent flow assuming mass conservation, incompressibility and pressurized flow. The water flow inside channels Q is computed by

(5)$$Q = {-}K\nabla \phi \comma \;$$

with

(6)$$K = \displaystyle{{\alpha {\lpar {r_i/2} \rpar }^{2/3}} \over {n_m\sqrt {\vert {\nabla \phi } \vert } }}\comma \;$$

where K corresponds to the channel hydraulic conductivity, with a circular cross-section α = πr_i ², and n_m = 0.04 m^−1/3s is the Manning friction coefficient for subglacial channels (e.g., Gulley and others, Reference Gulley2014).

The model is set up with prescribed water recharge from the tributaries and moulins that enters via subglacial channels. In addition, discharge at the glacier's outlet is modelled as atmospheric pressure Dirichlet boundary condition. The total residence times of tracers are calculated in two steps. First, tracer-transit times are computed by integrating the advective velocity along the subglacial channels and secondly, by adding the inflow modulation time (τ_i), which is a parameter to be inferred.

2.3 Parameter inversion strategy

The inversion aims to find the subglacial networks and hydraulic parameters that enable the model to fit the observations. As data are scarce and uncertain, we expect the solution to be highly nonunique, meaning that many networks can honour the observations. Therefore, we use a maximum likelihood approach where the goal is to explore the model space and find multiple conditioned subglacial (CS) systems. Here, we define a likelihood function, which is a measure of the misfit of the field data with the model outputs, to evaluate model parameters. A general formulation of a likelihood function, assuming independent Gaussian uncertainties for the data (e.g., Mosegaard and Tarantola, Reference Mosegaard and Tarantola1995) is given by

(7)$$L\lpar { {\bf m} {\rm \vert }\bf d} \rpar \propto {\rm exp}\lpar {-S} \rpar \comma \;$$

where

(8)$$S\lpar {\bf m} \rpar = \displaystyle{1 \over 2}\mathop \sum \limits_{i = 1}^n \left({\displaystyle{{F_i\lpar {\bf m} \rpar -{\bf d}_i} \over {\sigma_i}}} \right)^2\comma \;$$

with S the misfit function, m = [a, b, l_xy, s, f, T _d, τ_i] the model parameters and F the forward model (water flow model and subglacial channel generator). The forward model outputs F(m) (water pressure and tracer transit times) are based on a simulation run using m as parameters. Field data d = [d₁,…d_n] correspond to the observations, with n the total number of data. The standard deviation of the errors σ = [σ ₁,…σ_n] have to be estimated and should reflect not only instrumental errors, which are relatively small, but also the effect of averaging a point measurement over a model cell and model errors. The choice of the uncertainties is a subject of debate; for example, Brinkerhoff and others (Reference Brinkerhoff, Meyer, Bueler, Truffer and Bartholomaus2016) chose uncertainties similar to the magnitude of daily variations. However, the setup here differs as the inversion is performed for a snapshot of time. We run several inversions to test the effect of σ in the likelihood function and select a value that avoids overfitting but represents the uncertainties that each data source is subjected to, such as field measurement errors, model errors and limitations (e.g., mesh resolution).

Each data source is subjected to field measurement errors, which are added to model errors and limitations (e.g., mesh resolution). Note that Eqn (9) is a general formulation that is subsequently adapted for each kind of data, as is commonly done for joint inversion. Assuming independence, the total likelihood is the product of the individual likelihoods, which can be stated as

(9)$$L\lpar {\bf m{\rm \vert }\bf d}\rpar \propto {\rm exp}\left({-\mathop \sum \limits_j S_j} \right)\comma \;j\in \lcub {\rm p_{\rm w}\comma \;{\rm ts}\comma \;z} \rcub .$$

Here each misfit function S_j is designed to account for the particularities of the observational data type, where S _pw, S _ts and S _z correspond to water pressure observations, tracer-transit speeds and a correction term to account for piezometric level exceeding the surface elevation (see below).

Borehole water pressure data are subject to different sources of uncertainty. Furthermore, it has been observed that neighbouring boreholes can show significant differences in water level and behaviour (e.g., Rada and Schoof, Reference Rada and Schoof2018). Therefore, we have low confidence in the spatial representativeness of a measurement. The latter is implemented in the likelihood function by adding a tolerance to the borehole location, i.e., we select the modelled value within a radius r _bh which is closest to the measurement and use this in the likelihood. Then, the misfit function is stated as:

(10)$$\eqalignb{S_{\rm p_{\rm w}} &= \displaystyle{1 \over 2}\mathop \sum \limits_{i = 1}^n \left({\displaystyle{{{\rm min}\lpar {\vert {F_i\lpar {\bf m} \rpar -\;{\bf d}_{i\comma {\rm \gamma }}^{\rm p_{\rm w}} } \vert } \rpar } \over {\sigma_i^{{\rm p}_{\rm w}} }}} \right)^2\;\comma \;\;\; \cr &\quad {\rm \gamma }\in \lcub {{\rm \;}\forall \;x_{\rm \gamma }\comma \;y_{\rm \gamma }{\rm \;with\;}{\lpar {x_i-x_{\rm \gamma }} \rpar }^2 + {\lpar y_i-y_{\rm \gamma }\rpar }^2 \lt r_{{\rm bh}}^2 \;} \rcub \comma \;$$

where subscript γ refers to the neighbouring cells (coordinates x_γ, y_γ) within a distance r _bh of a borehole location (x_i,y_i). The standard deviation of borehole data are considered as $\sigma _i^{p_{\rm w}}$.

Tracer-transit times provide an estimate of subglacial water flow conditions. However, the total tracer resident times are strongly influenced by the inflow modulation time (time spent inside the moulin), which is estimated from water recharge into the moulin and its geometry. Within the data used in this study, there are no observations about recharge conditions into moulins. Consequently, observed transit times are only used to constrain or regularize the model into a range of physically plausible transit speeds (Schuler and others, Reference Schuler, Fischer and Gudmundsson2004; Werder and others, Reference Werder, Schuler and Funk2010). We define the binary variable I^ts as an indicator of the tracer-transit speeds within a physically reasonable range defined by ${\bf d}^{{\rm ts}}_{{\rm min}}$ and ${\bf d}^{{\rm ts}}_{{\rm max}}$. Transit speeds outside the physically reasonable range are then penalized through a likelihood function with standard deviation $\sigma _i^{{\rm ts}}$:

(11)$$\eqalign{S_{{\rm ts}} = & \displaystyle{1 \over 2}\mathop \sum \limits_{i = 1}^n \left({{\bi I}^{{\rm ts}}\displaystyle{{{\rm min}\lpar {\vert {F_{\bi i}\lpar {\bf m} \rpar -\bf d^{{\rm ts}}_{{\rm min}} } \vert \comma \;\vert {F_{\bi i}\lpar {\bf m} \rpar -\bf d^{{\rm ts}}_{{\rm max}} } \vert } \rpar } \over {\sigma_i^{{\rm ts}} }}} \right)^2\;\comma \;\cr \;{\bi I}^{{\rm ts}} = & \left\{{\matrix{{0\comma \;\;\;{\bf d}^{{\rm ts}}_{{\rm min}} \le F_i\lpar {\bf m} \rpar \le {\bf d}^{{\rm ts}}_{{\rm max}} \comma \;}\hfill \cr {1\comma \;\;\;{\bf d}^{{\rm ts}}_{{\rm min}} \gt F_i\lpar {\bf m} \rpar \;{\rm or}\;{\bf d}^{{\rm ts}}_{{\rm max}} \lt F_i\lpar {\bf m} \rpar .\;\;} \cr } } \right.} $$

Additionally, we assume that it is unlikely that the hydraulic head exceeds the surface elevation. To this end, we implement an equation that is activated only if water pressure exceeds surface elevation and penalizes the likelihood when the water level is higher than the surface elevation. This is implemented as a truncated Gaussian given by

(12)$$S_{\rm z} = \displaystyle{1 \over 2}\mathop \sum \limits_{i = 1}^n \left({{\bi I}^{\rm z}\displaystyle{{F_{\bi i}\lpar {\bf m} \rpar -{\bi z}_i} \over {\sigma_i^{\rm z} }}} \right)^2\;\comma \;\;\;{\bi I}^{\rm z} = \left\{{\matrix{ {0\comma \;\;\;F_i\lpar {\bf m} \rpar \le z_i\;} \cr {1\comma \;\;\;F_i\lpar {\bf m} \rpar \gt z_i\comma \;} \cr } } \right.$$

where I^z is an indicator corresponding to the index of nodes where F_i(m) has exceeded the surface elevation z_i with a standard deviation $\sigma _i^{\rm z}$.

One of the challenges in the model inversion is that we expect different channel networks with the correct hydraulic parameters to have a similar hydraulic response (i.e. to honour the observations). In other words, we expect to find several local maxima, which can be distant in the model space. In addition, there are nonlinearities and discontinuities in the likelihood function. For example, gradually modifying structural parameters (l_xy, s, f) can modify the channel network until a large reorganization is introduced. This is, for instance, the case when two parallel channels are being gradually pushed together until they merge, culminating in a larger restructuring of the network.

Consequently, we choose an inversion algorithm that explores the space thoroughly and avoids getting trapped in one local maximum. This is commonly done by Markov chain Monte-Carlo algorithms such as the Metropolis-Hasting algorithm (Metropolis and others, Reference Metropolis, Rosenbluth, Rosenbluth, Teller and Teller1953). Here, we use a more advanced algorithm, the Markov chain Monte-Carlo DREAM_(ZS) algorithm (Laloy and Vrugt, Reference Laloy and Vrugt2012). DREAM_(ZS) explores the model space similarly to a Metropolis-Hasting algorithm but includes multiple chains an adaptive sampling which facilitates a robust exploration of the model space and therefore it is able to find several local maxima more readily. In addition, we configure DREAM_(ZS) with different starting points to ensure an extensive model space exploration. As a result, DREAM_(ZS) captures the multimodal distribution of our problem, where each mode corresponds to a local maximum and therefore to a CS network. Moreover, it allows uncertainty quantifications of the model parameters for each explored local maximum. Note that this involves running the inversion procedure numerous times, which is feasible as our model is relatively computationally inexpensive.

2.4 Channel network structure persistence across the melt season

The proposed methodology finds sets of subglacial systems (or model parameters) for one snapshot. We refer to the set of inferred subglacial systems as CS systems, as they honour the observations. While this is acceptable for a single snapshot, if independent inversions are carried out for different snapshots, the spatial and topological dependence of the channel network structure across the melt season is not guaranteed. Similar to previous studies (Arnold and others, Reference Arnold, Richards, Willis and Sharp1998; Banwell and others, Reference Banwell, Willis and Arnold2013), we assume that the channel network structure does not change radically in the course of the melt season. While, changes in recharge during the course of the season can affect the hydraulic parameters and channel radii.

To ensure channel-architecture dependence between snapshots across the melt season, we force the parameters that define structural parameters of the subglacial channel generator (l_xy, s and f) to remain within a vicinity. For this, we implement the inversion in two steps: First, we infer a set of subglacial systems conditioned to a reference snapshot (labelled with subscript R: a _R, b _R, l_{xy, R}, s _R, f _R, T _d,R, τ_{i, R}), select manually one model (e.g., maximum likelihood mode) and extract the structural parameters (labelled with prime: l_xy’, s’, f’). The second step consists in inferring independently the subglacial systems of all other snapshots sε{1, …, 5}, limiting the exploration of the structural parameters to the vicinity of the selected model (l_xy’, s’, f’). The bounds are set in order to allow perturbations such as channel translation and local deformation to avoid large network reorganizations. This is done by sensitivity tests that constrain the bounds of l_xy’, s’ and f’ such that no large reorganizations are observed in the network. As a result, the inferred structural parameters for each snapshot (l_,xy,s’, s_s’, f_s’) are near the selected model. The inferred structural parameters for all snapshots are therefore correlated because they are forced to be in the surroundings of the same local maximum of the likelihood function, imposing a dependence across the melt season. Note that the channel radius parameters (a and b), transmissivity T _d of the distributed system and τ_i are not constrained to remain in the vicinity of the selected model (Fig. 2).

Fig. 2.

Parameter inversion strategy and snapshot dependence. First, the parameters for a reference snapshot are inferred and one model is selected (e.g., maximum likelihood model). For the following snapshots, the structural parameters are constrained to the vicinity of the structural parameters from the selected model.