2.2.1 Reference model: homogeneous, water-free glacier ice

The geometry and materials of the reference model are given in Figure 1a. The geometry includes a flat bedrock at 100 m depth and a subglacial channel with a radius of 2 m. We include the subglacial channel as a possible target for a GPR campaign. As such, the bedrock and the subglacial channel represent the two targets for which we will check how the imaging quality is affected by the model additions presented below.

Figure 1. 2D geometry of the investigated glacier models and relative permittivity ($\epsilon _r$) for (a) the reference model, (b) the additional wet snowpack, here 10 m thick, (c) the additional stochastic variation of ice permittivity (note the different color scale), and (d) the additional water inclusions (here LWC = 0.2 % and r _max = 0.1 m). The position of the bedrock (labeled ‘b’) and the subglacial channel (labeled ‘c’) are indicated by arrows for each model.

2.2.2 Model addition 1: wet snowpack at the glacier surface

Glacier ice is often overlain by snow or firn, and this layer might contain some liquid water. Such conditions are particularly prominent in spring, when GPR campaigns are often performed (e.g. Bauder and others, Reference Bauder2018). We assess the impact of such a layer by adding it to the surface of our reference model (Fig. 1b). The layer thickness is either 1 m or 10 m, which we consider being the range of a typical snowpack in Alpine settings. We calculate the layer's permittivity $\epsilon _s$ by using the parametrization suggested by Tiuri and others (Reference Tiuri, Sihvola, Nyfors and Hallikaiken1984):

(1)$$\epsilon_s = ( 0.1\, LWC + 0.8\, LWC\, ^2) \epsilon_w + \epsilon_d,\; $$

where 0.1 and 0.8 are two empirically determined coefficients, LWC is the liquid water content, $\epsilon _w = 80$ is the relative permittivity of the water (Table 2), and $\epsilon _d$ is the relative permittivity of dry snow. The latter is calculated from the density ratio between snow and water, that is ρ _snow/ρ _w (dimensionless):

(2)$$\epsilon_d = 1 + 1.7\times\rho_{snow}/\rho_{w} + 0.7\times( \rho_{snow}/\rho_{w}) ^2.$$

The wet snow conductivity σ (μS m⁻¹) is calculated following Granlund and others (Reference Granlund, Lundberg and Gustafsson2010):

(3)$$\sigma \approx 10 + 3\times10^3\, LWC.$$

With the above equations, a typical spring snowpack over glaciers with ρ _snow/ρ _w = 0.5 and LWC = 3 % (Griessinger and others, Reference Griessinger, Mohr and Jonas2018), results in $\epsilon _s = 2.3$ and σ = 10⁻⁴ S m⁻¹. These values are in good agreement with field observations (see e.g. Fig. 5 in Evans (Reference Evans1965)). Note that the value for $\epsilon _s$ is close to the permittivity of ice (see Table 2), and that we consider a bulk permittivity for the snowpack, i.e. we do not explicitly account for the snowpack's water inclusions. Our argument for doing so is that these water inclusions are expected to be very small when compared to the wavelength of the GPR signal in snow: at 25 MHz, the latter is in the order of 1 m, while the diameter of the water inclusions in snow are expected to be <1 mm (e.g. Coleou and others, Reference Coleou, Lesaffre, Brzoska, Ludwig and Boller2001). Moreover, we also ignore stochastic variations in permittivity that could occur because of a heterogeneous distribution of water content. We deem this omission to be acceptable after testing the effect that such a stochastic permittivity distribution would have in a 10 m thick snow pack (not shown) and after ascertaining that the effect is not large enough as to mask the strong diffraction patterns that we typically see in the field data and that we try to explain.

2.2.3 Model addition 2: heterogeneous ice permittivity

Measurements of the relative permittivity of ice $\epsilon _r$ (dimensionless) range between 2.89 and 3.26, with a mean value of ~3.2 (Robin and others, Reference Robin, Evans and Bailey1969; Johari and Charette, Reference Johari and Charette1975; Jezek and others, Reference Jezek, Clough, Bentley and Shabtaie1978; Plewes and Hubbard, Reference Plewes and Hubbard2001; Reynolds, Reference Reynolds2011; Bohleber and others, Reference Bohleber, Wagner and Eisen2012). Variations in $\epsilon _r$ occur due to the permittivity's dependence on ice density, temperature, and crystal orientation fabrics. The influence of ice density is discussed in Kovacs and others (Reference Kovacs, Gow and Morey1995), who proposed a slightly modified relationship proposed by Robin and others (Reference Robin, Evans and Bailey1969) for capturing such effects.

Ice density in alpine glaciers is most often considered to be homogeneous, and we thus expect $\epsilon _r$ to vary only slightly. Bohleber and others (Reference Bohleber, Wagner and Eisen2012), for example, reported variations in the order of a few percent (see their Fig. 4). Crystal orientation fabrics can also influence $\epsilon _r$, with variations in the order of 1 % (Johari and Charette, Reference Johari and Charette1975; Fujita and others, Reference Fujita, Mae and Matsuoka1993).

Here, we account for the natural variations in ice permittivity by imposing stochastic variations on $\epsilon _r$ in the range of 2.89 to 3.26 (Fig. 1c). The stochastic distribution is parameterized with a von Karman type correlation function (Goff and Holliger, Reference Goff and Holliger2012) described by a Hurst number 0.5 (that is an exponential distribution) and a correlation length of 10 m (both in the horizontal and the vertical dimension). The Hurst number (also known as the ‘fractal dimension’) characterizes the amount of heterogeneity in a natural medium (Goff and Holliger, Reference Goff and Holliger2012), and we will explore the sensitivity of this value in the Results section.

2.2.4 Model addition 3: scattering water inclusions

Water inclusions are modeled as randomly distributed, spherical scatterers. We constrain LWC and the size of the scatterers based on literature values. Barrett and others (Reference Barrett, Murray, Clark and Matsuoka2008) explain strong scattering in a surging glacier by the presence of water inclusions of multi-decimeter scale. Likewise, Hodge (Reference Hodge1976) observed englacial voids in boreholes, reporting that typical vertical extents were of several decimeters (see their Fig. 3).

LWC in temperate ice has been estimated from GPR by analyzing the electromagnetic wave velocity (Macheret and others, Reference Macheret, Moskalevsky and Vasilenko1993; Moore and others, Reference Moore1999; Murray and others, Reference Murray, Stuart, Fry, Gamble and Crabtree2000) or from the back-scattered power in individual GPR sections (Bamber, Reference Bamber1988; Hamran and others, Reference Hamran, Aarholt, Hagen and Mo1996; Macheret and Glazovsky, Reference Macheret and Glazovsky2000). Reported LWC values ranges from 0.5 % to 1.5 % in Murray and others (Reference Murray, Stuart, Fry, Gamble and Crabtree2000), from 0.3 % to 1.7 % in Raymond and Harrison (Reference Raymond and Harrison1975); Vallon and others (Reference Vallon, Petit and Fabre1976), and from 0 % to 9 % in Pettersson and others (Reference Pettersson, Jansson and Blatter2004).

More recently, LWC has been estimated from surface nuclear magnetic resonance (SNMR). SNMR is a geophysical technique that allows the direct detection and quantification of liquid water in the subsurface. It takes advantage of the magnetic moment and spin of the hydrogen nuclei of water. Traditionally applied in hydrological applications, the technique has shown promising results in glacier applications too (e.g. Hertrich and others, Reference Hertrich, Braun, Gunther, Green and Yaramanci2007; Legchenko and others, Reference Legchenko2011; Garambois and others, Reference Garambois, Legchenko, Vincent and Thibert2016). In summer 2008, SNMR was for example performed at the tongue of Rhonegletscher, a temperate glacier in Switzerland, yielding an average LWC estimates of 0.8 % ± 0.4 % for the sampled vertical profile (Hertrich and Walbrecker, Reference Hertrich and Walbrecker2008).

To test the effect of different configurations of distributed scatterers on the GPR signals, we perform simulations in which we (i) vary the LWC between 0.1 % and 1.5 %, with increments of 0.1 % (i.e. fifteen different values for LWC) and (ii) randomly vary the radius of the water inclusions between 0 and a maximal radius of either r _max = 0.1 m, r _max = 0.5 m, or r _max = 1.0 m. This results in a total of 15 × 3 = 45 simulations (Fig. 1d provides one example). The position of the scatterers is randomly generated but remains the same for each combination of LWC and r _max. This is to allow for comparisons between simulations. The di-electric properties of the water inclusions are the ones of glacial melt water (see Table 2).

2.3.1 Modeling algorithm

For modeling the GPR signal numerically, we use the open source software gprMax (Warren and others, Reference Warren, Giannopoulos and Giannakis2016). gprMax implements Yee's algorithm to solve Maxwell's equations in 2D or 3D using the finite-difference method in the time-domain (FDTD, Kunz and Luebbers, Reference Kunz and Luebbers1993). Here, we use the 2D configuration, for which gprMax uses the so-called transverse magnetic mode. This is achieved by setting the length of one of the horizontal dimensions to the spatial discretization, thus reducing that dimension to a single grid point. We use this 2D modeling approach (as opposed to 3D) because GPR field-data are most often migrated in 2D profiles and to reduce computational cost.

The source signal in gprMax is set to a Hertzian dipole with a dominant frequency of 25 MHz (a typical frequency for investigations on Alpine glaciers; e.g. Church and others, Reference Church, Grab, Schmelzbach, Bauder and Maurer2020; Grab and others, Reference Grab2021) and with a Ricker type source-time function. To mimic field measurements, we place the transmitter and receiver antennas at 0.5 m above the glacier surface and perpendicular to the investigated profile. The spacing between the transmitter and the receiver is kept constant at 4 m (corresponding to one wavelength in air at 25 MHz). The spatial increment of the antennas position along the profile (i.e. the trace spacing) is of 0.5 m. The length of the GPR profile for each simulations is 95 m and corresponds to 190 traces. gprMax antennas characteristics are summarized in Table 3.

Table 3. Time and space parameters for the gprMax simulations

In order to run the gprMax simulations, we discretize the glacier models defined in the previous Section in space and time. To avoid numerical dispersion, the space discretization length Δl should be ≤λ _min/10 (Warren and others, Reference Warren, Giannopoulos and Giannakis2016), where λ _min is the smallest wavelength of the propagating electromagnetic field. For a given frequency, λ _min is associated to the material with the smallest electromagnetic propagation velocity v _min. We calculate λ _min as follows:

(4)$$\lambda_{min} = {v_{\min}\over f_{\max}} = {c\over 3\, f\, \sqrt{\epsilon_r}},\; $$

where $\epsilon _r$ is the relative permittivity and f the central frequency (f _max = 3 × f as we consider as null the amplitude beyond three times the central frequency for a Ricker waveform). In our case, λ _min is found for water, which is the material with the largest relative permittivity (see Table 2) and thus the smallest velocity (v _water = 0.33 × 10⁸ m s⁻¹).

For f = 25 MHz and water, λ _min is 0.44 m, and we thus chose Δl = 0.05 m. This allows to speed up the simulations compared to Δl = 0.05 m by a factor of 5 (more information on computational time follows below). This means that the wavelength in the water is sampled by nine cells. The fact that we sample by nine cells instead of ten means that the highest frequency (and thus the shortest wave length) propagates with a velocity on the grid that is 0.93 % smaller than the desired velocity (Schneider, Reference Schneider2010) – a difference which we consider as being negligible. The time is discretized according to Δl and following the Courant-Freidrichs-Lewy stability condition (Warren and others, Reference Warren, Giannopoulos and Giannakis2016). The receiver recording time is set to 1.5 × 10⁻⁶ s, which corresponds to a penetration depth of the signal in ice of ~125 m (two-way travel time). A so-called perfectly matched layer width of ten cells (i.e. 0.5 m) is set on the model boundaries to absorb the signal and simulate an unbounded space (Berenger, Reference Berenger1996). Time and space model parameters for gprMax are summarized in Table 3.

Solving Maxwell's equations using the FDTD approach for high-resolution data is computationally expensive. To accelerate the simulations, we run gprMax on graphics processing units (GPUs). The FDTD discretization allows for a natural and efficient parallelization of the solver and allows leveraging the parallel processing capabilities of latest GPUs. We run the simulations using eight Nvidia A100 (SXM4, 40GB) GPUs. gprMax also allows for multi-GPU configurations, where independent trace computations are distributed among GPUs using message passing interface for distributed parallelization in a master-slave configuration. GPU computing permitted to speed up the simulations by a factor of 15 compared to multi-threaded central processing unit configurations. This results in a typical runtime for a single simulation of ~ 5 min. All data necessary to reproduce our gprMax simulations, including the MATLAB input files generator, are available in the Section Code and Data Availability.

2.3.2 GPR data processing

The gprMax output contains time series of the electromagnetic field strength for all grid cells and for all traces. As for field data, further processing is required to generate GPR sections that can actually be interpreted. For this, we employ our in-house Matlab-based toolbox GPRglaz (Grab and others, Reference Grab2018) and follow the processing workflow typically used for field-based investigations (e.g. Church and others, Reference Church, Grab, Schmelzbach, Bauder and Maurer2020; Grab and others, Reference Grab2021).

More specifically the workflow comprises (1) time zero correction based on the arrival of the direct wave, (2) bandpass filtering (10 MHz to 65 MHz) to cut undesirable low and high frequencies generated by numerical dispersion, and (3) image focusing and time-to-depth conversion that migrates the data with a constant radar wave velocity (0.167 m ns⁻¹ for ice; Glen and Paren, Reference Glen and Paren1975). Migration is performed with a Kirchhoff time migration scheme (Margrave and Lamoureux, Reference Margrave and Lamoureux2019). For access to the generated GPRglaz results, see the Section Code and Data Availability.