2.1. Surface melt timeseries

To estimate the timing and magnitude of seasonal meltwater inputs to the bed, we use the European Centre for Medium-Range Weather Forecasts (ECMWF)’s Reanalysis v5 (ERA5) (Muñoz-Sabater and others, Reference Muñoz-Sabater2021) as inputs to the temperature-indexed model by Litt and others Reference Litt(2019) to obtain spatio-temporally varying estimates for surface melt across the domain (Fig. 2). These ERA5 weather data are based on an array of field stations and weather models (Hersbach and others, Reference Hersbach2020) and directly provide estimates for snow cover, air temperature and total liquid precipitation across the 5 years (Muñoz-Sabater and others, Reference Muñoz-Sabater2021). Ice melt across the mesh is calculated using the temperature index (TI) melt parametrization from Litt and others (Reference Litt2019) (Fig. 2). We calculate daily melt over ice when the glacier surface is bare (using a TI of $6.5\,\mathrm{mm}^{\circ}\mathrm{C}^{-1}$ day⁻¹, computed from values from Litt and others Reference Litt(2019) and melt from snow for pixels that are snow covered (using an index of $4.1\,\mathrm{mm}\,^{\circ}\mathrm{C}^{-1}$ day⁻¹, following Braithwaite Reference Braithwaite(2008)). We scale the relative fraction of ice and snow melt per pixel using the relative snow cover data. While melt or surface runoff from rainfall from outside the model domain may also reach the model domain and eventually the glacier bed, we do not consider these inputs here. The TI model is shown to be more accurate for glaciers below 3500 m above sea level (a.s.l.) (Litt and others, Reference Litt2019), which is where most of Shishper’s tongue is located (Fig. 1). ERA5 data were downscaled from native 9 km to the model resolution (50 m) using a Kriging interpolation (Kusch and Davy, Reference Kusch and Davy2022). While some in situ climate data are available in the region, no station was operational in the vicinity of the glacier; using in situ data from an off-glacier station far away from the glacier would introduce its own set of uncertainties. Due to the relatively high temporal (1 day) and spatial ( $1\,\times\,1\,\mathrm{deg}$) resolutions, ERA5 data provide the best available estimate of meltwater inputs to the bed. SHAKTI is able to represent meltwater inputs as either point inputs or as distributed inputs; in this study, we apply the ERA5 melt estimate as a spatially distributed input over the bed, which is appropriate for heavily crevassed glaciers such as Shishper. The strong hydraulic coupling between surface and basal meltwater environments (Iken and Bindschadler, Reference Iken and Bindschadler1986; Zwally and others, Reference Zwally, Abdalati, Herring, Larsen, Saba and Steffen2002; Gulley and Benn, Reference Gulley and Benn2007; Shepherd and others, Reference Shepherd, Hubbard, Nienow, King, McMillan and Joughin2009; Miles and others, Reference Miles2017) has given us justification to make the assumption that all meltwater inputs to the bed (i.e. surface melt, rainwater, aquifer contributions) are instantaneous. Furthermore, the broken-up and crevassed nature of Shishper’s surface could allow for quicker delivery of meltwater to the bed.

Figure 2. (a) Englacial inputs to the transient subglacial hydrology model, averaged over the glacier, as calculated by ERA-5 Land and the temperature-indexed ablation model. (b) Average englacial input during the 2017 melt season (May through September). The red outline indicates the modeled domain.

3.1. Establishing winter base state

Before transient simulations can be run, the base winter state of the hydrological system must be established. To do this, we allow the drainage system to develop with zero external meltwater to the bed. During the winter, we assume that there is no surface or englacial melt, with geothermal flux and turbulent dissipation as the only sources of meltwater at the bed. Geothermal heat flux is set to 70 mW m⁻², which is within previously measured values in the area (Shengbiao and Jiyang, Reference Shengbiao and Jiyang2000). Note that we have prescribed the sliding velocity to be zero, so there is no frictional heating or cavity opening from sliding over bumps. Because we exclude all contributions from tributary glaciers, a Neumann boundary condition of zero flux is applied to all lateral edges of the domain. A Dirichlet boundary condition is applied to the near-terminus domain boundary, with hydraulic head equal to the bed elevation (i.e. water pressure equal to atmospheric pressure at the outflow). A time step of 1 day is used for obtaining the final equilibrated state.

We define equilibrium by assessing the time rate of change of gap height, basal water flux, hydraulic head and effective pressure. We deem the model ‘equilibrated’ if there is no visible growth or decay in the minimum, maximum and spatial mean values of each of these parameters after 500 days; for example, mean effective pressure changes at a constant rate of  2e–7 % per year at the end of the winter equilibration. Once all output parameters reach equilibrium, after  600 days, there is formation of a primary drainage channel down the main trunk of the glacier (Fig. 3a). It is also worthwhile to note that the channel has formed in the absence of any surface water melt, indicating its potential to persist through the winter months just given a small amount of meltwater from geothermal flux and turbulent dissipation.

Figure 3. Basal flux across the modeled domain following (a) a ‘winter state’ equilibration spinup with no melt inputs to the system (b) a transient simulation through a full calendar year, including a summer melt season and return back to frozen winter conditions. (c) The difference between the two equilibrated states.

Beginning from the base winter state (Fig. 3a), we run a transient simulation of 1 year (January 1–December 31). Following this year, the model reaches a new stable winter state (Fig. 3b). The second stable state is largely similar to the first, but shows more efficient, concentrated drainage at a few areas, including the terminus and up-glacier at 4028 km N. Running additional melt seasons yields no additional changes in winter drainage patterns, indicating a new equilibrium. This perennial channel then forms the basis for the subglacial system during the melt season.

3.2. Seasonal evolution of subglacial hydrology

To understand how Shishper’s subglacial drainage network responds to seasonal changes in meltwater flux, we run transient simulations across a period of 5 years, 2017–21, using a timestep of 30 minutes. The transient input for these simulations is the temporally and spatially varying sum of ice melt, snow melt and liquid precipitation (Fig. 2), applied as distributed meltwater inputs to the subglacial system throughout our model domain of the main glacier trunk. Potential incoming melt inputs from tributary glaciers are not included.

Figure 4 illustrates changes in the configuration of the drainage system throughout 2017, which is representative of the pattern observed across all 5 years. We see a mostly closed system in winter (Fig. 4b), which transitions to a highly efficient, channelized system at the peak of the melt season (Fig. 4c). The basal flux mirrors the surface melt input trend, peaking around August (Fig. 2a), while hydraulic head and effective pressure stay mostly steady, apart from spikes at the beginning and end of the melt season. At the height of the melt season, the drainage system extends to the northernmost part of the domain, splitting into arborescent patterns characteristic of channelized drainage. By October 5, these channels then disappear, with the upper part of the system having completely shut down. Finally, the system returns to the winter state by late October (Fig. 4d and e).

Figure 4. (a) Model outputs for 2017, including hydraulic head, basal flux and effective pressure. Mean, min and max refer to the spatially averaged mean and the minimum and maximum values over the mesh. (b) Log ₁₀ basal flux across the glacier at four times during the year: January 1 (winter), August 1 (peak melt), October 5 (drawdown of the drainage network at the end of the melt season) and October 18 (return to winter conditions).

The lower channel, which traverses the mid- to lower trunk clearly persists through every simulated winter in 2017–21, and can be seen in both images of the ‘closed’ state (Fig. 4a, d and e). We know that this channel appears during the winter equilibration, during which time the only water at the ice–bed interface comes from turbulent dissipation and geothermal heat flux. There is always a consistent stream of water, although small, that keeps the main channel open. Bhambri and others Reference Bhambri(2020) show that surface melt elevations move from 6400 m in peak summer to 3500 m at the end of winter (no surface melt is observed in December, January, or February) meaning that the bottom part of the glacier will always receive more melt, and is more likely to contain channels, than the top.

Figure 5 presents a closer look at the rapid decreases in effective pressure at the beginning of the melt season (May–July). As shown in Fig. 5a, coming from primarily distributed winter drainage with low transmissivity, the rise in hydraulic head due to the system’s inability to transport growing fluxes, and the rapid fall in head back to the equilibrium value, show that the system resolves spikes in water pressure by developing more efficient pathways (i.e. increasing transmissivity by opening new channels). The calculated spikes in hydraulic head in Figs. 4 and 5 are higher than realistic physical values, in which localized buildups of very high water pressure would more quickly be resolved through hydraulic jacking (local uplift where water pressure exceeds flotation) and/or fracturing of the overlying ice. Since these processes are not explicitly represented within SHAKTI, localized large water pressures may be resolved more slowly in the simulations, thus appearing as non-physical values. Setting a warmer ice temperature may also result in less extreme spikes (see Appendix C). Such a buildup of hydraulic head can be observed in Fig. 5b (June 5), where a large area of negative N (high water pressure) can be seen at the northern part of the domain. On June 10, this area has relaxed, and by June 30, the entire section has almost completely returned to the original state of effective pressure, around 2 MPa across the mesh. Figure 6 depicts the channel system that is established during and after these events, showing that an area of distributed, heavy flow around 4029 and 4030 km N quickly coalesces to a narrow and efficient channel in response to higher water pressures.

Figure 5. Top: (a) Melt input (blue) overlaid with spatially averaged hydraulic head (red) during 2017. Bottom: pressures across the mesh during (b) and after (c) the spike in hydraulic head in early June. Gray contours indicate effective pressure of 0 MPa (flotation, where ice overburden equals water pressure).

Figure 6. Basal fluxes surrounding an early-season spike (depicted in Fig. 5) show a transition at the upper trunk from distributed, sheetlike flow to efficient, channelized flow. The red arrows highlight the formation of a channel that occurs between June 5 and June 30.

So long as high fluxes continue, melt opening exceeds creep closure, keeping efficient channels open during the majority of the melt season. The drainage system is able to quickly shuttle large fluxes through, allowing it to return to a low-pressure state and draining the surrounding bed. Although velocities are not simulated here, it is inferred that sliding velocities would decrease due to a return to higher effective pressures in the summer. A velocity dataset developed by Beaud and others Reference Beaud, Aati, Delaney, Adhikari and Avouac(2022) at Shishper Glacier from 2013–19 shows that the glacier does indeed slow down significantly during summer months. In addition, increases in surface displacement further up the trunk of Shishper were observed by Bhambri and others Reference Bhambri(2020) during the early melt season (May to June) between 2013–16, suggesting that there could be decreased effective pressures at the northern part of the domain during this time. This agrees with our model results: near the terminus, the system remains perennially channelized, while the upper part sees an inefficient, distributed system during the early melt season that evolves to become more efficient over the summer.

As the system closes and the capacity of the drainage system falls, it regains its sensitivity to temporary increases in melt, as is seen in the early and late summer spikes in hydraulic head (Fig. 5) (Hart and others, Reference Hart, Young, Baurley, Robson and Martinez2022). This contraction happens as basal flux falls, allowing melt opening to fall and creep closure to dominate. The spikes are smaller than the ones at the beginning of the melt season because the system has not had much time to close yet, so it is more efficient than at the beginning of spring.

Overall, these findings corroborate the established understanding that there is a transition from a distributed to channelized drainage system and back during the course of the year (Fig. 4) (Schoof, Reference Schoof2010; Werder and others, Reference Werder, Hewitt, Schoof and Flowers2013; Flowers, Reference Flowers2015). As long as high meltwater fluxes persist, melt opening exceeds creep closure, maintaining open channels throughout most of the melt season. As the system shuts down and the drainage capacity decreases toward the end of the melt season, it exhibits heightened sensitivity to melt increases, as evidenced in early and late summer hydraulic head spikes (Fig. 5).

4.1. Hydrological insights into surge dynamics

Comparing the modeled effective pressures with observed surge phases implies that incipient surge motion in November 2017 and subsequent slow acceleration through the winter 2017-18 do not show up as a clear hydrological signal in our simulations, suggesting that there could be a process or mechanism not accounted for by our model. However, significant hydraulic head spikes do correspond with rapid acceleration in June 2018, suggesting that elevated water pressures could play a role in escalating already-occurring ice motion (Kamb, Reference Kamb1987, Björnsson, Reference Björnsson1998).

Figure 7 overlays effective pressure simulated by SHAKTI on top of satellite-derived velocity observations from Beaud and others Reference Beaud, Aati, Delaney, Adhikari and Avouac(2022). Observations show a pre-surge acceleration begins in November 2017, but the model outputs indicate a decrease in effective pressure during this acceleration (Kamb, Reference Kamb1987; Björnsson, Reference Björnsson1998). At the beginning of June 2018, Bhambri and others Reference Bhambri(2020) describe a rapid but brief acceleration, which corresponds to the peak of  5.5 m d⁻¹ described by Beaud and others Reference Beaud, Aati, Delaney, Adhikari and Avouac(2022) at the same time, coinciding with a series of modeled spikes in hydraulic head at the beginning of the 2018 melt season. As the drainage system enters its efficient summer state, the surge then enters a very slow ‘semi-quiescent’ period during which velocity is only slightly higher than normal summer velocities, lasting until September 2018 (Beaud and others, Reference Beaud, Aati, Delaney, Adhikari and Avouac2022). The glacier then accelerates again, reaching speeds of  2 m d⁻¹ by November 2018 and 3.5 m d⁻¹ in January 2019. Another surge peak occurs from late April to early May 2019 (Bhambri and others, Reference Bhambri2020). A small GLOF of the ice-dammed lake, which damaged the Karakoram Highway, follows from June 22–23, 2019 (Bhambri and others, Reference Bhambri2020; Beaud and others, Reference Beaud, Aati, Delaney, Adhikari and Avouac2022).

Figure 7. Glacier surface velocities from the dataset of Beaud and others Reference Beaud, Aati, Delaney, Adhikari and Avouac(2022) overlaid on model outputs of basal flux and effective pressure during the 2017–19 surge. The bright red line indicates a GLOF that occurred on June 22–23, 2019.

Our simulated spring and fall dips in effective pressure correspond with the observations by Beaud and others Reference Beaud, Aati, Delaney, Adhikari and Avouac(2022) of observations of spring and fall speedups at Shishper Glacier even during quiescent (non-surging) periods. The model results show larger and longer-duration effective pressure drops in spring compared to fall, aligning with observations of larger spring speedups. These spikes in hydraulic head appear more extreme than what may be expected in real life, in which localized buildups of very high water pressure would more quickly be resolved through hydraulic jacking and/or fracturing of the overlying ice. Overall, these findings support the hypotheses of observational studies suggesting that seasonal hydrology evolution is largely driving seasonal glacier motion trends in HMA (e.g. Nanni and others, Reference Nanni, Scherler, Ayoub, Millan, Herman and Avouac2023).

4.2. Limitations and future directions

Subglacial hydrology is likely only one of several factors that may drive surge behavior. To further disentangle the drivers of surge motion, it is necessary to consider and model additional processes such as frictional feedbacks due to sliding at the ice–bed interface, basal melting due to changes in the pressure melting point, till deformation, uplift and hydrofracture, dynamic advances and retreat of the terminus, and changes in ice thickness at the reservoir and receiving zone of the glacier (e.g. Flowers and others, Reference Flowers, Roux, Pimentel and Schoof2011; Liu and others, Reference Iken, Röthlisberger, Flotron and Haeberli2024). Furthermore, our model results hint that abrupt transitions from unstable, high water pressures to low (sub-flotation) pressures could play a role in slowdowns in surge motion. To quantify the role of subglacial hydrology in ice motion, a coupled model is necessary. Two-way coupling of SHAKTI with ice dynamics in ISSM has been implemented and applied recently to Helheim Glacier, Greenland (Sommers and others, Reference Sommers2024); implementing a similar coupled framework for this glacier could provide further insights into these complex interactions that are important for understanding the motion of surging glaciers. In addition, we have neglected the hydrological influence of upper-elevation tributary glaciers; although we do not expect large hydrological contributions from the tributaries due to their high elevation, the magnitude of hydrological flux from these tributaries may be non-trivial and ought to be considered in future work. Additional contributions from groundwater flow may also affect subglacial hydrology. Future studies should focus on integrating these processes into the model to better understand the interplay between subglacial hydrology, ice dynamics, ice-dammed lake floods, and surge behavior.