2.1. GPR data acquisition

In this paper, we analyze three pseudo-3-D Common Offset (CO) GPR data sets that were acquired during the month of July in 2015, 2016 and 2019, over the Lower Calderone Glacieret (Fig. 2). The applied signal processing was limited to drift (a.k.a., time-zero or zero timing) correction, DC removal and a Butterworth band-pass filter. Even though migration is commonly applied to reconstruct the geometrically correct radar reflectivity distribution within the subsurface, especially regarding dipping reflectors (Jol, Reference Jol2009), this process was not used for the analysis. In particular, a correct migration analysis would (a) require an accurate EM velocity distribution as input, which is not yet known; (b) need equally spaced traces, which could necessitate the use of a rubber-band interpolation between dedicated marker points, in case of irregular spatial acquisition rates causing a stretching of the GPR image in-between such points (Jol, Reference Jol2009); and (c) potentially negatively impact the recovery of the ice-bedrock interface, which in most of the analyzed data sets is highlighted by interfering diffraction hyperbolas, rather than clear laterally coherent reflections.

Figure 2. Trace positioning over the Lower Calderone Glacieret. The figure shows (a) a view of the Calderone Cirque from a photo taken by Dr Massimo Pecci on 15th September 2016; (b) the 3-D DTM of the Cirque obtained from the 2016 photogrammetric survey, with the contour lines plotted at 10 m elevation intervals, and the GPR survey lines of 2015 (black lines), 2016 (gray lines) and 2019 (light gray lines), superimposed; and (c) the normal versor (blue arrow) of a generic surface, resulting from the vector product of two gradient-based surface versors (black arrows), and used for the 3-D projection of the corresponding GPR trace. For reference, the positions (brown dots) of the nearby mountain peaks (Fig. 1a) are also highlighted in (b), with the mountain summit placed at the origin of both the easting and northing axes.

The three 2015 CO GPR profiles were acquired using a Zond-12e Radsys GPR system, equipped with 150 MHz air-coupled (hand-held) bistatic unshielded antennas (Monaco and Scozzafava, Reference Monaco and Scozzafava2017), with a transmitter–receiver offset of about 2.15 m and an average elevation above the ground-surface of ~20 cm. The same GPR system was later used to acquire the ten 2016 CO GPR profiles, two of which roughly coincide with the transversal profiles of the 2015 dataset (Fig. 2b). In absence of a GPS device during the data acquisition, the various GPR profiles were positioned using fixed reference points whose distance and elevation differences were measured with a Nikon Forestry Pro II Laser Rangefinder-Hypsometer (Monaco and Scozzafava, Reference Monaco and Scozzafava2017). In the presented analysis, the GPS coordinates of the western (42°28'10.596''N, 13°33'55.404''E) and eastern (42°28'19.812''N, 13°34'15.024''E) peaks of Mt. Corno Grande (Fig. 1a) were also used as a further constraint for the trace positioning (Fig. 2b).

The four 2019 CO GPR profiles were instead acquired using a PulseEkko Pro GPR system equipped with 250 MHz ground-coupled bistatic Sensors & Software Inc. shielded antennas, with a transmitter-receiver offset equal to 27.94 cm. The various GPR profiles were positioned using specific markers that were accurately recorded at regular intervals along the corresponding survey lines.

A photogrammetric survey (Pecci and others, Reference Pecci, Cappelletti, Esposito, D'Aquila and Caira2017) was also carried out on 15th September 2016 (i.e. at the end of the ablation season), from which a Digital Terrain Model (DTM) was constructed (Fig. 2b). Considering the initial approximate 13 × 13 cm resolution, the Point Sampling Tool plug-in of the QGIS open source software was used to discretize the entire surface of the Calderone cirque into a 1 × 1 m grid for the analysis. The obtained DTM was then used as a reference surface to study the glacieret volume, by comparing it with the basal interfaces constructed over the same grid from each GPR survey. For georeferencing purposes, a few GPS measurements were further acquired at specific reference points on the glacieret surface, such as large boulders (Pecci and others, Reference Pecci, Cappelletti, Esposito, D'Aquila and Caira2017).

It is important to point out that the use of the same 2016 DTM in all three cases may introduce an additional uncertainty factor, due to potentially significant variations in the surface topography (either local or global) with respect to both 2015 and 2019, that could be caused by changes in both the glacieret volume and the debris cover. Nevertheless, the use of a reference DTM is necessary for a more accurate estimation of the glacieret volume, in absence of a specific DTM for each year, especially considering the highly variable topography of the surveyed area (Pecci and others, Reference Pecci, Visconti, Beniston, Iannorelli and Barba2001).

2.2. Time-to-depth conversion

The basal interface of the Lower Glacieret was recovered using an automated reflection strength tracking algorithm designed to track the recorded reflections accurately and objectively along the various GPR profiles (Dossi and others, Reference Dossi2022a). As an example, the horizons marking the main reflections within the longitudinal profiles of the various GPR surveys are highlighted in Figure 3a, showing no significant internal stratigraphy. This lack of internal reflections, combined with the significant presence of surface debris, prevents the implementation of an amplitude inversion algorithm designed to recover the subsurface EM velocity distribution from the identified reflection amplitudes and arrival times (Forte and others, Reference Forte, Dossi, Pipan and Colucci2014; Dossi and others, Reference Dossi, Forte, Pipan and Colucci2018).

Figure 3. Auto-tracking results for the 2015 (first row), 2016 (second row) and 2019 (third row) longitudinal GPR profiles. In each row, the figure shows (a) the auto-tracked horizons (green lines) marking the main recorded reflections, superimposed to the reflection strength profile; and (b) the auto-picked diffraction hyperbolas, superimposed to the corresponding signal amplitude profile, with positive amplitudes marked in green and negative amplitudes marked in red.

As an alternative, the hyperbolic diffractions within the various GPR profiles were recovered using an automated diffraction picking algorithm designed to detect subsurface scatterers objectively, track the diffraction phases originating from them accurately, and recover the average subsurface EM velocity above each scatterer, among other possible analyses (Dossi and others, Reference Dossi2022b, Reference Dossi2024). The hyperbolas constructed from the aforementioned longitudinal profiles are shown in Figure 3b, and they accurately mark most of the recorded diffractions. As it can be noticed from the results, however, the number of clear undistorted diffractions is limited to a few dozens, which makes the resulting EM velocity model more susceptible to the presence of false positives. In fact, to avoid a significant number of noise-related false negatives, we intentionally did not apply the automated grouping analysis in Figure 3b, which disregards isolated false positives by requiring each constructed hyperbola to have at least one other hyperbola of opposite polarity marking another phase of the same diffraction event (Dossi and others, Reference Dossi2022b, Reference Dossi2024).

The shape of the available diffractions can also be affected by (a) the possibly erroneous positioning of the individual GPR traces; (b) the possible presence of out-of-plane diffractions, whose in-plane projections would be placed at the wrong depths; and (c) substantial signal interference, random noise and clutters (Dossi and others, Reference Dossi2022b, Reference Dossi2024). More importantly, the identified diffractions in Figure 3b are mostly concentrated in the shallower section of the glacieret, as in all the other GPR profiles, therefore no significant information regarding the EM velocity within the deeper region can be recovered with this method. As a result of all these issues, it was determined that a statistically sound EM velocity distribution within the Lower Calderone Glacieret could not be recovered from the available GPR data.

For the time-to-depth conversion, we therefore used a reference EM velocity equal to 0.168 m ns⁻¹, corresponding to pure ice (Looyenga, Reference Looyenga1965), and an associated uncertainty of 10%. The possible glacial systems covered by the considered EM velocities thus range between compact firn at the higher end (Looyenga, Reference Looyenga1965; Robin, Reference Robin1975; Kovacs and others, Reference Kovacs, Gow and Morey1995), and ice containing liquid water for about 2.5–3% of the total volume at the lower end, as estimated from volumetric mixing models (Birchak and others, Reference Birchak, Gardner, Hipp and Victor1974). The selected uncertainty can also be assumed to cover the irregular 0.05–1.5 m thick surface debris layer (Rovelli, Reference Rovelli2006), for which the effect on the total cumulative EM velocity is difficult to be determined locally, with the EM velocity for limestone being equal to 0.12 m ns⁻¹ (Davis and Annan, Reference Davis and Annan1989).

In any case, the debris cover will have an overall negligible effect in the calculation of the total thickness, particularly in the deeper areas of the glacieret, when compared to other possible sources of uncertainty, which include (a) possible local deviations from the globally-applied data acquisition and signal processing parameters, such as the utilized trace interval and drift correction; (b) the automatically picked arrival times of the basal reflections, which correspond to the individual peaks of the phase-independent reflection strength in each GPR trace (Fig. 3a; Dossi and others, Reference Dossi2022a), and can be negatively affected by significant noise and interference; (c) the avoidance of migration processes in the applied signal processing, which require accurate EM velocity distributions as input to move dipping reflectors to their correct positions within GPR profiles (Jol, Reference Jol2009); and (d) the normal projections of the estimated thicknesses onto the glacieret surface (Fig. 2c; discussed in the following section), which can be affected by local outliers in the DTM (Fig. 2b), as well as erroneous trace positioning.

2.3. Digital elevation model of the glacieret base

After the time-to-depth conversion, the tracked basal reflections were projected onto the vertical axes of the individual GPR traces, which were locally estimated from the surrounding topography. In particular, the versor $\hat{n}_{i,j}$ normal to the DTM at a given trace position is calculated through the vector product of the two vectors $\vec{x}_{i,j}$ and $\vec{y}_{i,j}$ (Fig. 2c), which are obtained from the respective components of the local gradient vector of the DTM:

(1)$$\hat{n}_{i,j} = \displaystyle{{{\vec{x}}_{i,j} } \over {\vert {{\vec{x}}_{i,j} } \vert }} \times \displaystyle{{{\vec{y}}_{i,j} } \over {\vert {{\vec{y}}_{i,j} } \vert }}$$

with

(2)$$\vec{x}_{i,j} = \left({1, \;0, \;\displaystyle{{{\rm DTM}_{i,j + 1} -{\rm DTM}_{i,j-1} } \over {2\Delta x}}} \right)$$

(3)$$\vec{y}_{i,j} = \left({0, \;1, \;\displaystyle{{{\rm DTM}_{i + 1,j} -{\rm DTM}_{i-1,j} } \over {2\Delta x}}} \right)$$

where (j, i) is the closest gridpoint to the considered GPR trace position, and Δx is the space interval (i.e. 1 m) used to discretize both the easting and northing positions within the grid. To avoid possible outliers in the calculated normal versors, potentially caused by either isolated artifacts or peculiar small-scale changes in the topography, the gradient vector in each position (whose components are used in Eqns. (2), (3)) was substituted with an average of the local gradient vectors of the DTM (i.e. within a 10 m radius).

After positioning the basal lines within the 3-D model, these were combined with the contour lines of the DTM outside of the glacieret surface (Fig. 2b), to construct a digital elevation model (DEM) of the glacieret base. More specifically, the surrounding contour lines were marked from the DTM at 5 m elevation intervals and used as a boundary condition during the interpolation process, while the extent of the debris-covered glacieret was roughly inferred from the thicknesses estimated at the edges of the various GPR surveys, as well as from the available photographic data. Furthermore, to avoid data redundancy and reduce computational costs, given the high linear density of GPR traces when compared to the grid resolution, the basal lines were re-sampled at 0.5 m elevation intervals using a simple 3-D linear interpolation between adjacent GPR traces.

The elevation of the basal DEM at the various grid positions was calculated using the adjusted IDW spatial interpolation method presented by Li and others (Reference Li, Wang, Ma and Wu2018). Considering N _H elevation points that belong to either the basal or contour lines, the elevations h _k of these points, and their horizontal distances d _k from the interpolation point located at the (j, i) grid position, the elevation of the DEM at such position is given by the following weighted average (Achilleos, Reference Achilleos2011; Rui and others, Reference Rui, Yu, Lu, Ashraf and Song2016; Li and others, Reference Li, Wang, Ma and Wu2018):

(4)$${\rm DEM}_{i,j} = \displaystyle{{\mathop \sum \nolimits_k w_kh_k/d_k^p } \over {\mathop \sum \nolimits_k w_k/d_k^p }}$$

with

(5)$$d_k = \Delta x\sqrt {{( {i-i_k} ) }^2 + {( {\,j-j_k} ) }^2} $$

$$( {j, \;i} ) \ne ( {j_k, \;i_k} ) $$

$$k = 1, \;\;2, \;\ldots , \;\;N_H$$

$$p = 2$$

where (j _k, i _k) and w _k are respectively the position and adjusting parameter of the k-th point of the set; and the exponent p defines the type of interpolation used, namely (assuming all w _k being equal to 1) either a moving average (i.e. p = 0), a linear interpolation (i.e. p = 1), or a weighted moving average (i.e. p > 1). In fact, the higher the value of p is, the smoother the resulting DEM surface becomes (Li and others, Reference Li, Wang, Ma and Wu2018).

For the construction of the set of N _H elevation points, we used linear segments branching out of the considered (j, i) grid position at regular angular intervals Δϕ (e.g. 15°), to mark the crossed elevation points along the N _L (e.g. 2) closest basal or contour lines to be reached by the segment each time. In addition, after crossing the closest line, each segment is iteratively rotated counterclockwise by Δϕ/N _L for each of the remaining N _L − 1 lines to be crossed, to avoid the adjusting parameter of the next crossing point to be identically null due to the latter being directly behind the previous point. In particular, the adjusting parameters w _k, which may not be commonly applied in IDW interpolations (Achilleos, Reference Achilleos2011), are used in Eqn. (4) to reduce the influence of the elevation points further away from the analyzed interpolation point, due to the presence of closer elevation points in-between (Li and others, Reference Li, Wang, Ma and Wu2018).

In the calculation of the adjusting parameters, the marked N _H elevation points are re-arranged by increasing values of d _k (Eqn. (5)). As each point effectively casts a shadow onto the points further away, the resulting cumulative effect onto the k-th elevation point, caused by some of the k − 1 closer points, is based on the relative angular positions of the former with respect to each one of the latter. In particular, the adjusting parameter for the k-th elevation point is given by (Li and others, Reference Li, Wang, Ma and Wu2018):

(6)$$w_k = \left\{{\matrix{ 1 & {{\rm if}} & {k = 1} \cr {\mathop \prod \limits_{m = 1}^{k-1} {\sin }^p[ {\theta_{k,m} } ] } & {{\rm if}} & {k = 2, \;\;3, \;\ldots , \;N_H} \cr } } \right.$$

with

(7)$$\theta _{k,m} = \left\{{\matrix{ {\displaystyle{\pi \over 2}} & {{\rm if}} & {\alpha_{k,m} \ge \alpha_{\rm max}} \cr {\theta_{k,m} } & {{\rm if}} & {\alpha_{k,m} < \alpha_{\rm max}} \cr } } \right.$$

(8)$$\alpha _{{\rm max}} = {\rm max}\left[{\Delta \phi , \;\displaystyle{{2\pi \cdot N_L} \over {N_H}}} \right]$$

where θ _k,m is the angle formed by the segment connecting the compared k-th and m-th elevation points, and the segment connecting the interpolation point with the midpoint of the first segment; α _k,m is the angle formed by such elevation points, with the vertex placed on the interpolation point; α _max is the maximum angle for α _k,m, above which the closer m-th point does not cast a shadow onto the k-th point further away; and max[…] is an operator that provides the maximum value among those listed within its argument.

As it can be noticed from Eqn. (7), when the angle α _k,m is equal or greater than α _max, the angle θ _k,m is automatically set equal to π/2, which in turn sets the corresponding factor in Eqn. (6) equal to 1, thus canceling out the influence of the latter in the calculation of w _k. Therefore, the elevation points that have no other point located between them and the interpolation point, will have an uninfluential adjusting parameter w _k (i.e. equal to 1). Notice that the product in Eqn. (6) only considers the elevation points that are closer than the k-th point to the interpolation point, while the first elevation point of the set (i.e. k = 1) has a value of w _k equal to one (Eqn. (6)), since by construction it has no other elevation point in-between.

Given the potentially large number N _H of elevation points involved in the IDW interpolation at each grid position, the angular step Δϕ is used as a minimum value for α _max in Eqn. (8), to prevent the latter from becoming uselessly small in Eqn. (7). In addition, the set number N _L of the closest contour or basal lines involved in the analysis is added as a factor in Eqn. (8), as opposed to the formula used in Li and others (Reference Li, Wang, Ma and Wu2018), since the analyzed elevation points are not randomly distributed, but rather selected through a geometrically determined process. The added factor thus further prevents the resulting angle from becoming too small, and roughly defines the average angular interval within each of the N _L constructed arrays.

2.4. Potential DEM artifacts

Common IDW interpolations generally perform better when the sampled elevation points are regularly distributed, while possible artifacts include the topographic island effect, by which both hills and basins are turned flat within the innermost circles in topographic maps; and the bull's eye effect, by which isolated DEM peaks stick out at the various elevation positions (Achilleos, Reference Achilleos2011; Li and others, Reference Li, Wang, Ma and Wu2018).

The latter effect is caused by the significantly smaller distance d _k of a given elevation point when the IDW interpolation is performed in its neighborhood, which disproportionally increases the weight of such point by almost turning it into a singularity (Eqn. (4)). The added adjusting parameters w _k (Eqn. (6)) counteract these artifacts by reducing the influence of the points further away while increasing the relative weight of the closer ones (Fig. 4), which likely have elevations similar to the considered point, although the distorting effect may not completely disappear (Li and others, Reference Li, Wang, Ma and Wu2018). For instance, the alternation between the constructed basal and contour lines and the void areas in-between caused a slight stair-stepping effect (a.k.a., staircase effect) that rendered those lines noticeable in the resulting DEMs of the bedrock.

Figure 4. Exemplary shadow effect between two elevation points, used to prevent bull's eye artifacts during the IDW spatial interpolation. The figure shows (a) the interpolation point (blue dot), the first elevation point (gray dot), and the different (numbered) positions of the second point (brown dots), with the segments (dashed lines) separately connecting the interpolation point with the elevation points in the various cases, and with the angle α _2,1 (Eqn. (8)) at the first position highlighted (yellow sector); and (b) the same geometry as in (a), with one set of segments (solid lines) connecting the two elevation points (gray and brown dots) in the different cases, and the other (dashed lines) connecting the interpolation point (blue dot) to the midpoints (red dots) of the former in said cases, and with the angle θ _2,1 (Eqns. (7), (9)) at the first position highlighted (yellow sector). The figure also shows (c) the angles α _2,1 (blue dots) and θ _2,1 (red dots) formed in the various cases by the segments in (a) and (b), as well as the maximum value α _max (dashed line), set equal to 15° in this example; and (d) the elevation (blue dots) extrapolated in the interpolation point in the different geometries, compared to the constant elevations for the first (gray line) and second (brown line) points, chosen as an example.

As an example of the shadow effect between two elevation points in the adjusted IDW spatial interpolation, Figure 4 shows the effect of the adjusting parameter w ₂ of the second point, for 11 different positions with respect to the (closer) first one. In the considered case, Eqn. (4) is simplified into the following equation:

(9)$${\rm DEM}_{i,j} = \displaystyle{{( h_1/d_1^2 ) + {( {( \sin [ {\theta_{2,1}} ] ) /d_2} ) }^2h_2} \over {( 1/d_1^2 ) + {( {( \sin [ {\theta_{2,1}} ] ) /d_2} ) }^2}}$$

The effects of the shadow cast by the first elevation point onto the second one are visible in Figure 4d at the positions 3–8 of the second point. Most notably, an abrupt change in the interpolated elevation can be noticed between the positions 8 and 9 (Fig. 4d), caused by the angle α _2,1 surpassing the threshold α _max (Fig. 4c), while the asymmetry in the graphs is mainly caused by the increasing distance d ₂ (Fig. 4a).