2.1.1 Glaciovolcanic caves

An analytical solution to an arbitrary, nonradially symmetric void geometry does not exist. Despite the theoretical limitations associated with Eqn (2), the equation is still regarded to hold merit for geometries that strictly violate the assumptions used for its derivation (e.g., Nye, Reference Nye1976). It has been used to model nonradially symmetric hydrological passageways and cavities (e.g., Walder, Reference Walder1986; Hooke and others, Reference Hooke, Laumann and Kohler1990; Creyts and Schoof, Reference Creyts and Schoof2009), as well as large (r = H/4) symmetrical voids formed due to subglacial volcanic eruptions (Tuffen, Reference Tuffen2007). Similarly to Hooke and others (Reference Hooke, Laumann and Kohler1990), we employ Eqn (2) to describe the creep closure of nonradially symmetric glaciovolcanic caves by defining an effective void radius that varies along the void surface. Instead of void radius r in Eqn (2), we introduce normal radius r _n (Fig. 3). The normal radius is the radial distance between the cave surface and the z-axis, perpendicular to the cave surface, and is defined as $r_n = \mathbf{r} \;\cdot$ $\hat{\mathbf{n}}$, where $\mathbf{r}$ is the point on the cave surface, and $\hat{\mathbf{n}}$ is the unit normal vector to the cave surface (Fig. 3). We approximate the normal stress as the hydrostatic stress, thus replacing ρ _igH in Eqn (2) with ρ _ig (H − z). Based on these assumptions, and Eqn (2), the creep closure at any point along the surface can then be written

(5)$$-{1\over r_n} {{\rm d} r_n\over {\rm d} t} = k A \left({\rho_{\rm i} g ( H-z) \over n}\right)^n.$$

Note that in the limit r/H → 0, Eqn (5) reduces to Eqn (2) of Nye (Reference Nye1953). Similarly, the melt rate normal to the cave surface is

(6)$${{\rm d} r_n\over {\rm d} t} = {\dot{q}\over \rho_{\rm i} L},\; $$

and the balance between creep closure and melt opening becomes

(7)$$r_n = {\dot{q}\over k A \rho_{{\rm i}} L} \left({n\over \rho_{\rm i} g \left(H - z\right)}\right)^n.$$

The geometries given by Eqn (7), and the associated closure rate Eqn (5), were tested with a numerical ice-flow model and show improved results compared to radially symmetric geometries Eqn (4) with uniform closure rates Eqn (2) (Fig. S1).

Figure 3. Schematic diagram of an arbitrary noncylindrical cave geometry. At any point on the cave surface, described by $\mathbf{r}$, the surface normal at that point, $\hat {\mathbf{n}}$, defines a radial distance between the surface and the vertical z-axis that is normal to the cave surface, given by ${\bf r}_n$. The point of intersection with the ${\cal Z}$-axis is O _n and the azimuth angles of $\mathbf{r}$ and ${\bf r}_n$ are θ and θ _n, respectively.

2.1.2 Glaciovolcanic chimneys

We model chimneys as radially symmetric about a vertical central axis, with the possibility of a depth-dependent radius, leading to variable cross-sectional area. The radial closure of englacial tunnels Eqn (2), and variations thereof, has previously been used to model vertical hydraulic conduits (Röthlisberger, Reference Röthlisberger1972) and moulins (e.g., Catania and Neumann, Reference Catania and Neumann2010; Andrews and others, Reference Andrews, Poinar and Trunz2022). We thus apply the formulation to glaciovolcanic chimneys, which are geometrically similar vertical features. Allowing a variable cross-sectional area strictly violates the assumptions used to derive the equation for the contraction of cylindrical voids Eqn (2), as nonradial strain rates would be induced along the axis of chimneys. However, realistic chimney geometries should not vary greatly in radius over short distances, and they should have vanishing strain rates at the glacier surface, just as described by Eqn (2). To account for the variable cross-sectional area, we rewrite Eqn (4) as

(8)$$r( z) = {\dot{q}( z) \over k A \rho_{\rm i} L} \left({n\over \rho_{\rm i} g ( H-z) }\right)^n.$$

The total heat flux required to keep a chimney in steady state is therefore

(9)$$\dot{Q} = 2 \pi \rho_{{\rm i}} L A {\int}_{0}^H r( z) ^2 \left({\rho_{{\rm i}} g ( H-z) \over n} \right)^n dz.$$

2.1.3 Glaciovolcanic chimney advection

The above formulations neglect ice dynamics aside from those induced by the chimneys themselves. Such chimneys would only evolve according to variations in the geothermal input and radially symmetric creep closure. To determine the effect of glacier dynamics on chimneys, background flow fields must be considered. Incorporating background flow fields into the analytical chimney models is nontrivial, and is thus not attempted here. Rather, we propose a physics-based conceptual model of the evolution of a chimney. For simplicity let us consider a glacier of constant thickness H, and infinite width and length resting on an inclined bed. The coordinate system is aligned with the glacier: ${\cal X}$ is along the bed in the direction of flow, ${\cal Y}$ is along the bed but perpendicular to ${\cal X}$, and ${\cal Z}$ is normal to the bed. The glacier is subjected to a bed-parallel velocity field, which is chosen to be represented by the shallow-ice approximation:

(10)$$v_{\cal X}( {\cal Z}) = {2 A\over n + 1} \tau_b^n H \left(1 - \left(1 - {{\cal Z}\over H} \right)^{n + 1} \right),\; $$

where τ _b is the basal shear stress, assumed equal to the driving stress (Cuffey and Paterson, Reference Cuffey and Paterson2010). An incipient cylindrical chimney of radius R is present at the centre of the coordinate system, and we assume it is aligned with the ${\cal Z}$-axis to simplify the analysis. This chimney now begins to passively advect downstream, i.e., we assume the chimney does not induce creep closure nor affect the flow field, in a manner determined by the velocity profile Eqn (10), which here is set constant in time (Fig. S2a). The chimney is elongated over time (Fig. S2b), and its surface area is hence simultaneously enlarged Eqn. S3. However, as the height and the ${\cal X}{\cal Y}$-parallel cross-sectional area of the chimney remain constant, Cavalieri's principle dictates that the chimney volume stays constant as well. If the geothermal input stays fixed, then the constant volume of geothermal gases must dissipate the heat over the growing surface area. The specific melt rate will thus decrease, allowing creep closure to constrict the chimney. Further, as the chimney is advected down glacier, its lower effective cross-sectional area, perpendicular to the centreline of the chimney, decreases (Fig. S2c). These two mechanisms can close the chimney, or facilitate blockages of incoming debris, ice, or snow. Any sliding along the bed, as may be expected for temperate mountain glaciers, would serve to accelerate the advection of chimneys away from their sources.

2.2.1 Model setup and parameters

To further investigate the interactions between geothermally induced ice melt and glacier dynamics, we perform a set of forward numerical model simulations using synthetic glacier geometries. Our model employs two modules that run sequentially to capture the transient evolution of glaciovolcanic voids (Fig. S3).

1. 1. The ice-flow module employs Elmer/Ice, a three-dimensional (3-D) finite-element ice-flow model (Gagliardini and others, Reference Gagliardini2013), to solve the Stokes equations (e.g., Pattyn and others, Reference Pattyn2008). This module takes in a mesh of the model domain, runs a diagnostic Elmer/Ice simulation to initialise variables, and then continuously deforms the model domain, i.e., the free surfaces associated with the void and glacier, by running a fixed number of prognostic Elmer/Ice simulations. A diagnostic simulation is required before each prognostic simulation to initialise the variables for the input mesh, as extrapolating variables after remeshing yielded poor results. The default setup runs four iterations using 6-hour time steps during each prognostic simulation, as this combination yielded the most stable simulations for all parameter ensembles during model testing. Note that the melt is not applied to the void within this module.

2. 2. The melt and remeshing module is written in Python and instantaneously applies the geothermally induced melt associated with the modelled time interval to the void, and then remeshes the model domain. This module takes in the deformed mesh and extracts the free surfaces of the void and glacier. Both surfaces are remeshed using the Python application programming interface of the open source 3-D finite-element mesh generator GMSH (Geuzaine and Remacle, Reference Geuzaine and Remacle2009), and the melt is applied to the void surface using the Python package PyVista (Sullivan and Kaszynski, Reference Sullivan and Kaszynski2019). Finally, the void and glacier surfaces are used to reassemble the model domain and the volume is remeshed. Note that deformation due to ice dynamics is not applied within this module.

During model development, we attempted to simulate ice flow and geothermal melt entirely within Elmer/Ice, instead of treating these processes sequentially in the two modules described above, but this strategy proved unsuccessful for three main reasons that follow (Unnsteinsson, Reference Unnsteinsson2022). (i) Instabilities quickly arise and can distort the void surface into a irregular nonphysical geometry. This problem arises from the relatively large deformation and melt rates that can warp mesh elements to the point that they overlap. A solution would require both reduced time steps, on the order of minutes, and very fine, sub-metre, mesh resolutions in most cases, along with frequent remeshing to guarantee the integrity of the mesh. Such a solution would be immensely computationally inefficient, and cannot be applied to features of large spatial and temporal scales. (ii) Elmer/Ice does not currently have a solver that can create and remesh an unstructured 3-D mesh, thus requiring an external solution. (iii) The way surface normal vectors are computed in numerical models results in nodes that define the void–bed interface to be lifted off the bed when melt is applied. Hence the void–bed boundary is transferred to the distal end of an affected cell, resulting in additional synthetic void growth on the scale of the mesh resolution. The solution is either the same as for the first problem, which suffers from the same drawbacks, or to manipulate melt implementation at the boundary externally.

For the reasons above, we devised the two-step procedure, which allowed us to model glaciovolcanic voids for an array of realistic physical parameters, while maintaining computational feasibility. The model was run for a total of 1232 parameter ensembles, with four input parameters that were varied between simulations. The input parameters are: glacier thicknesses ${50}\, {\rm m } \leq H \leq {200}\, {\rm m }$, chosen to be representative of mountain glaciers where glaciovolcanic voids have been observed; bed/surface slopes ${0}^{\rm o} \leq \alpha \leq \, {15}^{\rm o}$; total geothermal heat fluxes ${0.5}\, {\rm MW } \leq \dot {Q} \leq {10}\, {\rm MW }$, inspired by measured values for fumaroles and hot springs (Gaudin and others, Reference Gaudin2016); and four different heat transfer mechanisms (see below). Simulations run until they either crash, or are terminated when (i) the void width becomes 75 % of the domain width; (ii) the void height drops below 2 m; or (iii) time or iteration number limits are reached. The terminations due to void width and height limitations are imposed to prevent interference with boundary conditions and the disappearance of a free surface, respectively. Note that the model will crash when a void reaches the surface, as Elmer/Ice does not handle the merging of free surfaces. While we allow these simulations to run until they crash, we define melt-through to occur when the void height exceeds 90 % of the glacier thickness. With this step-wise approach, 48 hours of run time, in serial with 4000 MB allocated memory on a computer cluster, delivered up to 800 days of simulated time, depending on input parameters.

2.2.2 Model domain

With the aim of investigating a broad glaciological and volcanological parameter space, laterally limited domains of uniform ice thickness are used (Fig. 4). Compared to modelling fully realistic glacier geometries, this approach offers several advantages: (i) simplicity in changing glaciological parameters, i.e., glacier thickness and the bed/surface slope, hence velocity field; (ii) reduction of necessary computational resources due to considering only the area likely to be influenced by a glaciovolcanic void, and (iii) simplification of the interpretation of simulation results. The initiation of void formation cannot be modelled numerically, thus requiring an incipient void to be prescribed. The domain mesh is created using the Python application programming interface for GMSH, and all geometrical entities are automatically labelled so as to be compatible with Elmer/Ice (Unnsteinsson, Reference Unnsteinsson2022).

Figure 4. The numerical model domain (a) cross-sectional view and (b) bottom view. The glacier thickness H and bed/surface slope α are given, and the horizontal extent of the domain is set to be double the glacier thickness in both directions, with vertical boundaries on all sides. Note the mesh refinement around the proto-void (enlarged here for better visualisation).

2.2.3 Initial and boundary conditions

Both the glacier surface and the surface of the void are modelled as stress-free, i.e.,

(11)$$\sigma \cdot \mathbf{n}_{{\rm S}} = 0,\; $$

where $\mathbf{n}_{{\rm S}}$ is the normal vector to the ice surface. The void- and glacier surface are both subject to zero surface mass balance within the Elmer/Ice module, as the geothermally induced melt is implemented within the Python module. The four vertical sides of the model domain can be split into two groups that we will term passive boundaries (PBs) and active boundaries (ABs). Passive boundaries are those parallel to glacier flow on sloped model domains and all vertical boundaries on horizontal model domains. All passive boundaries have a prescribed no-flux condition:

(12)$$\mathbf{v} \cdot \mathbf{n}_{\rm PB} = 0,\; $$

where $\mathbf{n}_{{\rm PB}}$ is the normal vector to the passive boundary. While it would be possible to implement stress conditions here to simulate, for example, the drag of valley walls, in our case, this would only serve to alter glacier velocities which are already controlled by the slope. Active boundaries (ABs) are those that are perpendicular to glacier flow on sloped model domains, i.e., the upstream and downstream boundaries. For active boundaries we prescribe a vertical profile of slope-parallel velocity according to the shallow-ice approximation Eqn. (10). We chose the shallow-ice approximation boundary condition to have a standardised flux boundary condition across all model domains. Periodic boundary conditions could also have been used.

This study is restricted to fully water-drained glaciovolcanic voids, the observed existence of which suggests that efficient subglacial drainage is possible in these environments such that water pressure cannot be maintained. Observations of the crater glacier of Mount St. Helens (WA, USA), which hosts a glaciovolcanic cave network (e.g., Anderson and others, Reference Anderson, Behrens, Floyd and Vining1998), suggest that permeable bed geology inhibits basal water accumulation and thus the water pressures that would enhance sliding (Walder and others, Reference Walder, LaHusen, Vallance and Schilling2005). It is therefore reasonable to assume that fast sliding is likely not a significant contributor to ice flow where glaciovolcanic voids form. Nonetheless, a temperate glacier flowing down the flank of a volcano would still be expected to demonstrate basal slip, at least in the form of regelation and enhanced creep (e.g, Weertman, Reference Weertman1957), with the possible addition of bed deformation (e.g., Iverson and others, Reference Iverson, Hooyer and Baker1998). Implementing sliding/friction laws into the model would, however, increase the number of model parameters that could be varied, increase the number of simulations needed and consequently complicate the analysis. Investigating the impact of sliding on the formation and evolution of glaciovolcanic voids is thus reserved for future work. We therefore impose a no-slip boundary condition at the bed, i.e., $\mathbf{v}( {\it z}_{\rm bed}) = \rm 0$.

For the Elmer/Ice module, zero velocity and pressure fields are used as initial conditions for the diagnostic and prognostic simulations. During these simulations, the Stokes equations are solved to satisfy the boundary conditions above. Thus, the void is only subjected to ice deformation during the prognostic Elmer/Ice simulations of each module iteration. The geothermally induced melt is only applied to the void after the prognostic step, via the Python module.

2.2.4 Melt implementation

The manner in which heat fluxes are distributed within the void is of vital importance, as the expansion/shrinkage of different sectors of a void is dictated by the heat transfer to those sectors. Gas flow within glaciovolcanic voids is complex (e.g., Florea and others, Reference Florea, Pflitsch, Cartaya and Stenner2021), and accounting for the various mass- and heat-transfer mechanisms among the gas, glacier ice, and associated melt water would render such physically detailed modelling approaches impractical. Assumptions about the mass flux, vapour and chemical concentrations, and the initial temperature would have to be made to estimate the effect of processes such as vapour condensation, radiation and liquid film dynamics (Woodcock and others, Reference Woodcock, Gilbert and Lane2015, Reference Woodcock, Lane and Gilbert2016). Modelling gas flow within glaciovolcanic voids is computationally intensive in itself (Curtis, Reference Curtis2016), so accounting for these processes would demand more computational resources and further complicate analysis of results. We therefore rely on simple mathematical approximations of the heat transport within the voids instead of resolving the gas flow and associated processes. The total heat flux available for melting is specified and remains constant, while the specific heat fluxes at the void surface are computed based on the approximations below. The four different approximations of heat transport within voids, each meant to represent a physically plausible scenario, are:

1. M1 The case where low temperature geothermal sources are only capable of elevating the ambient temperature within a void, but do not drive vigorous vertical convection. The total heat flux, $\dot {Q}$, is thus distributed uniformly along the entire void surface, ${\cal S}$, with specific heat flux $\dot {q} = \dot {Q} / {\cal S}$.

2. M2 A geothermal gas plume driven by either natural or forced convection. The plume is assumed to be cylindrical, with radius r _plume, and the total heat flux is evenly distributed over the plume surface. Outside the plume, the specific heat flux decays radially as dictated by thermal radiation, $\dot {q} \propto \dot {Q} / r$. Should any portion of the void surface be within the plume, r < r _plume, the specific heat flux acting on that portion is prescribed to be the same as at the plume surface.

3. M3 A geothermal gas plume driven by either natural or forced convection, like M2, but the plume conforms to void geometry. This is done by setting the centre line of the plume to follow the centre line of the void, analogous to fluid flow in a tube. As for M2, the specific heat flux decays radially from the plume, and is kept constant within the plume.

4. M4 A geothermal point source with inefficient heat transport, with the specific heat flux away from the source set as thermal radiation from a point source: $\dot {q} \propto \dot {Q} / r^2$. As with M2 and M3, the specific heat flux is kept constant within a given radial distance.

The heat transport modes can be classified as “vertical modes” and “nonvertical modes”, depending on the presence or absence of vertical preference, respectively. M1 and M4 are nonvertical as their formulations essentially describe them as point sources, which distribute specific heat fluxes based on either surface area or total radial distance. For the vertical modes, M2 and M3, the heat sources are assumed to be (sub-)vertical and specific heat fluxes are distributed uniformly along their (sub-)vertical axes, but decay radially away from the axes.

For a given total heat flux and heat transport mode, the specific heat flux at each node of the void surface can be computed. The melt rate normal to the ice surface at each node is subsequently computed according to Eqn (6). Any node of the mesh, P_t, at time t, is then translated to node

(13)$$\eqalign{{\rm P}_{t + \Delta t}& = {\rm P}_{t} + {{\rm d}r_n\over {\rm d}t} \Delta t \hat{\mathbf{n}}_{\rm P} \cr & = {\rm P}_{t} + {\dot{q}( {\rm P}_{t}) \Delta t\over \rho_{{\rm i}} L} \hat{\mathbf{n}}_{\rm P},\; }$$

at time t + Δt, with $\dot {q}( {\rm P}_{t})$ the specific heat flux at node P_t and $\hat {\mathbf{n}}_{\rm P}$ the unit normal vector to the void surface at node P_t.