Seismic processing

We processed the data for imaging and amplitude analysis using SeisSpace ProMAX 2-D. For both seismic datasets, we employed a processing workflow as shown in Fig. 2. It includes two output datasets: (1) amplitude analysis with minimal data processing applied, and (2) for basal and englacial imaging. The seismic pre-processing included correcting for surface topography, attenuating the various noise types within the data and shaping the frequency spectrum. Noise suppression included trace editing, low cut filtering, surface wave attenuation, time-frequency domain filtering and direct arrival muting. The surface waves were attenuated using a frequency-wavenumber (FK) filter, with an automatic gain control (AGC) applied prior to filtering and removed after the filter application. We applied a 2:1 trace interpolation prior to surface wave attenuation on the 2017 dataset to unwrap the spatially aliased energies as the receiver spacing was increased between the 2012 and 2017 seismic acquisitions. Our choice of velocities was determined through conventional velocity analysis on common midpoints using semblance picking. A constant ice-velocity model of 3700 ms⁻¹ was identified to be appropriate for the migrations.

Fig. 2. Seismic processing workflow for 2012 and 2017 datasets.

We tested two different migration algorithms, namely Kirchhoff and reverse time migration (RTM), for providing a structural interpretation for englacial and basal reflectors. During post-imaging processing, we applied time-variant filtering to improve the signal-to-noise ratio and an amplitude scaling to balance the sections.

Seismic imaging results

The pre-processed and migrated sections are shown in Fig. 3. Both seismic datasets provide a highly resolved continuous but rugose basal interface (Fig. 3, yellow arrows). These profiles are acquired and migrated in 2D and therefore reflections may originate from slightly out-of-plane. The migrated images for both seismic datasets provide a strong positive amplitude (black) basement reflection indicating, as expected, an increase in acoustic impedance between the glacial ice and bedrock. We expect the bedrock to be granite with a potential thin till layer, as observed from surrounding deglaciated areas and previous borehole studies on Rhone glacier (Sugiyama and others, Reference Sugiyama2008). The reflected basal amplitude varies because of basal topography and heterogeneous basal conditions. There is little change in the basal topography between 2012 and 2017. A lower noise content is observed in 2012 as a result of the higher common depth point (CDP) fold and the thicker ice in 2012 provided less interference between surface waves and the basal reflections. The amplitude spectrum before and after spectral whitening (Figs 3b and f) highlights that there is a similar bandwidth for both seismic datasets. Prior to spectral whitening the data has a dominant frequency of 100 Hz and after spectral whitening the data has similar spectra up to 1000 Hz.

Fig. 3. Seismic processing images orientated East-West (A'-A as labelled on Figure 1): (a) 2012 pre-migration stacked image, (b) 2012 Frequency spectrum before and after spectral whitening, (c) 2012 Pre-Stack Kirchhoff migrated stacked image, (d) 2012 Reverse Time Migration stacked imaged. (e)–(h) Corresponding images for the 2017 dataset. Yellow and blue arrows represent the bedrock and englacial interpretations, respectively, and the white horizon represents the glacier surface.

There are some imaging differences between the pre-stack Kirchhoff time migration and the RTM. However, for both 2012 and 2017 the migration algorithms provide similar basal and englacial imaging. The 2012 Kirchhoff imaging provides improved basal continuity in comparison to the RTM, however, an identical basal structure is interpreted using the 2012 RTM. Improvements using the RTM over the Kirchhoff are observed in sub-basal reflectors as a result of the RTM using accurate wave physics in order to reposition the reflectors as opposed to an approximation with the Kirchhoff migration. The 2017 basal reflector has improved continuity using the RTM algorithm in comparison to the Kirchhoff migration. The two migration algorithms complement each other and assist in the interpretation.

Significant differences are observed in the englacial reflectivity between 2012 and 2017 seismic datasets. There is subtle evidence of an englacial reflection in 2012, but the more recent 2017 dataset shows a much stronger negative amplitude englacial reflection (Fig. 3, blue arrows). The seismic reflector increases in amplitude and continuity between the 2012 and 2017 data, implying a significant change in englacial conditions. The stronger amplitudes in 2017 indicate a larger absolute acoustic impedance contrast compared to the 2012 data.

The RTM algorithm provided improved imaging of the englacial feature in 2017 as the englacial reflector can be tracked down to the basal reflector. Englacial seismic and GPR reflections within glaciers have been observed in several field studies and were characterised as a change in c-axis orientation (Horgan and others, Reference Horgan2008; Polom and others, Reference Polom, Hofstede, Diez and Eisen2014), englacial conduits (Stuart, Reference Stuart2003) or engrained sediments (Murray and Booth, Reference Murray and Booth2009). In order to investigate the cause of the englacial reflection, we applied the seismic amplitude variation with angle (AVA) technique to the 2017 seismic data.

Seismic amplitude analysis

Englacial material properties can be estimated by analysing the seismic amplitude of the reflected waves. The recorded amplitude from the englacially reflected seismic wave is a function of incidence angle and elastic properties (density and seismic wave velocities) of the two media creating the interface. This technique has been successful in classifying basal conditions on Greenland and Antarctic ice sheets (Anandakrishnan, Reference Anandakrishnan2003; Peters and others, Reference Peters2008; Booth and others, Reference Booth2012; Dow and others, Reference Dow2013) and identifying subglacial lakes (Peters and others, Reference Peters2008). The angle-dependent reflectivity can be calculated using the Zoeppritz equations (e.g. Aki and Richards, Reference Aki and Richards2002). Even though temperate glacier ice is anisotropic and heterogeneous, we assume that this has a negligible impact on the reflectivity analysis. Temperate ice elastic properties can be estimated through a literature review (Table 2). Therefore, only the elastic properties from the englacial reflector are unknown. Our aim from the AVA technique is to determine the elastic properties from the englacial reflector using the 2017 seismic data.

Table 2. Seismic properties of temperate ice and water employed for the AVA analysis (Peters and others, Reference Peters2008; Bradford and others, Reference Bradford, Nichols, Harper and Meierbachtol2013)

The angle-dependent p-wave reflection coefficient R(θ) is a function of the reflected amplitude A _r(θ), source amplitude A ₀, reflected waves incidence angle θ, ray path length d(θ) and anelastic attenuation coefficient α_p. The angle-dependent reflectivity can be expressed as (Peters and others, Reference Peters2008; Dow and others, Reference Dow2013):

(1)$$ R(\theta) = {{A_{\rm r} (\theta)} \over {A_0 d_{\rm r} (\theta)e^{(\alpha_{\rm p}.d(\theta))}}} $$

We extracted the reflected amplitude, A _r(θ), by picking the englacial reflection on 54 shot gathers, where the englacial reflection was well visible (blue arrows in Fig. 4a). The path length (d(θ)) was estimated based upon the acquisition and englacial reflection geometry assuming straight rays travelling at a constant 3700 m s⁻¹ velocity. The source amplitude can be obtained from the squared primary amplitudes of the englacial reflection and the first order multiple of the englacial reflection at normal incidence (Dow and others, Reference Dow2013):

(2)$$ A_0 = {{A_{\rm r} (0)^2} \over {A_{\rm m} (0)}} {{d_{\rm r} (0)} \over {2}}, $$

Fig. 4. Amplitude analysis of englacial reflection from 2017 data. (a) Example shot gather showing englacial reflection picking (blue arrows) (b) Misfit function, sum of squared errors, between calculated AVA reflectivity and datapoints. A constant density of 800 kg m⁻³ is displayed to determine the best fitting AVA curve. (c) Reflectivity versus angle analysis. Black line indicates calculated reflectivity data and the errorbars indicate two standard deviations from the reflectivity data calculated using the Dow and others (Reference Dow2013) inversion methodology, the red curve indicates the theoretical ice-water reflectivity and the green curve indicates the best fitting reflectivity.

where A _m is the first order multiple amplitude at normal incidence. The 2017 Rhone Glacier seismic data did not produce a clear first order simple multiple. Therefore, we calculated the angle-dependent reflectivity of the englacial reflection using the methodology described by Dow and others (Reference Dow2013). We calculated simulated reflectivity curves using Eqn (1) for a narrow range of plausible A ₀ and attenuation parameters. The source amplitude A ₀ was estimated with Eqn (2); using a narrow range of physically plausible A _m values from zero to maximum primary amplitude observed at normal incidence.

P-wave anelastic attenuation is often expressed as the seismic quality (Q _p), which is inversely proportional to the anelastic attenuation coefficient (α_p) (Eqn 3). For obtaining an estimate of Q _p, we considered seismic cross-hole measurements performed in the fall 2018 within the ablation area on the Rhone Glacier. The estimated Q _p value was 100 ± 20, which is in good agreement with other studies (Westphal, Reference Westphal1965; Peters and others, Reference Peters, Anandakrishnan, Alley and Voigt2012; Babcock and Bradford, Reference Babcock and Bradford2014). We varied the Q _p correction between 80 and 120. From these values of Q _p we calculated a range of anelastic attenuation coefficients α_p using the relationship expressed in Eqn (3) (Gusmeroli and others, Reference Gusmeroli2010; Peters and others, Reference Peters, Anandakrishnan, Alley and Voigt2012).

(3)$$ Q_{\rm p}= {{\pi f} \over {V_P \alpha(\,f)}} $$

We calculated reflectivity data points using Eqn (1) with the range of α_p and A ₀ values as described above. We rejected the reflectivity points with values <−1 or >0 (no positive amplitudes were observed during picking). Mean values and standard deviations of the calculated reflectivity data are shown in Fig. 4c. Additionally, we computed the theoretical reflectivity curve for an ice/water interface using the values in Table 2. The theoretical curve lies well in the range of the corrected reflectivity data.

To determine the best fitting elastic parameters, we performed a grid search over a range of elastic parameters (P-wave velocity between 1000 and 3800 m s⁻¹, S-wave velocity between 0 and 2000 m s⁻¹, and density between 700 and 2000 kg m⁻³). We calculated theoretical AVA curves using the Zoeppritz equations and calculated the misfit to be the sum of squared errors between all the data points and the calculated theoretical AVA curves. The best fitting elastic parameters, where the misfit was minimised, was with a P-wave velocity of 1790 m s⁻¹, S-wave velocity of 30 m s⁻¹ and density of 800 kg m⁻³. In Fig. 4b, the misfit is shown for different P-wave and S-wave velocities and with a constant 800 kg m⁻³ density, with the best fitting parameter marked by a white dot. The angle-dependent reflectivity curve using the best fitting englacial elastic parameters is shown by the green curve in Fig. 4c. These elastic parameters indicate the englacial reflection is likely caused by the presence of water.

In addition to the source amplitude and attenuation corrections that we have applied, the seismic angle-dependent reflectivity result can be influenced by other factors, such as FK filter distortions and shot and geophone coupling effects. The FK filter recovered the englacial seismic reflections that were interfering with surface waves. In Fig. 4c, we observe larger standard deviations for low incidence angles. Here, the reflections were possibly contaminated by surface waves and we attribute the large standard deviations to residual surface wave energy. It should be noted that AVA analysis would not have been possible for low incidence angles without the application of the FK filter.

Shot or geophone coupling corrections were not performed as previous studies found this correction to be insensitive to the calculated reflectivity (Zechmann and others, Reference Zechmann2018). Additionally, we anticipated this variation to be relatively small in comparison to the large range of first order multiple amplitude values and p-wave attenuation parameters used in Eqn (1).

The seismic AVA analysis provided clear evidence that the englacial reflection, appearing in the 2017 dataset, is caused by an impedance contrast originating from ice (top)/water (bottom) interface (Fig. 4c). However, the AVA analysis was unable to yield an estimate of the thickness of the water layer, that is, it is unclear if it represents an englacial conduit or a larger subglacial water accumulation.

Subglacial lakes and englacial cavities filled with water have been documented on Glacier de Tête Rousse in the French Alps (Vincent and others, Reference Vincent2012). If the englacial reflection would originate from a subglacial lake or an englacial water-filled cavity, this would result in a significant low-velocity anomaly within the glacier. Since we have employed a constant and identical velocity for the migration of the 2012 and 2017 datasets, one would expect a downward shift of the basal reflector in the 2017 data, if a pronounced low-velocity zone would be present. This is clearly not the case and the basal topography remains at a consistent elevation under the englacial feature. It is therefore highly unlikely that an englacial void or subglacial lake is responsible for the englacial reflection, and it must be interpreted as an englacial conduit. Its thickness must be < ~4 m. Otherwise, one would observe reflections from the upper and lower boundary of the conduit, which is not the case. Based on the minimum layer thickness detectability (Sheriff, Reference Sheriff2002), the conduit's minimum thickness is estimated to be ~0.5 m.

Drilling

After confirming the englacial feature was visible during 2018 from the GPR data and determining the spatial extent, we drilled six boreholes (BH) in and around the englacial feature (Fig. 5; red points). Two boreholes (BH3 and BH4) were drilled directly into the feature at a depth of 88.0 and 87.5 m, respectively, whilst the remaining four boreholes (BH1, BH2, BH5 and BH6) were drilled around the englacial feature down to depths of 97.2, 104.8, 101.7 and 105.4 m, respectively. Both boreholes drilled into the englacial feature (BH3 and BH4), drained immediately upon connection to the englacial feature, and this resulted in an increased tension on the drilling hose. From the remaining four boreholes, only BH5 hit the bed providing depth control during time-to-depth conversions for both the seismic and GPR datasets. The other three boreholes (BH1, BH2, BH6) were terminated ~5 m above the bedrock. BH2, BH5 and BH6 remained water filled throughout the campaign (21 July--22 August), and we infer that they did not pass through any englacial void as a result of the constant hose tension during drilling. BH1 remained water filled for the first 2 weeks of the campaign before draining in the middle of August. We can speculate that the borehole (BH1) made a hydrological connection to the englacial feature through a fracture caused by hydrofracturing as a result of the short-term increase in englacial water pressure (see subsection Borehole Water Pressure)

Borehole camera

We lowered the camera into BH3, BH4 and BH5 to observe englacial conditions and the basal interface. The basal interface, observed in BH5, was a granite bedrock covered by numerous small rocks and pebbles. Direct englacial observations were unable to be made in borehole BH3 due to turbiditic water reducing visibility. The following observations were made for BH4, which penetrated into the englacial feature:

1. 1. The englacial water was murky and turbiditic, with a visibility ~20–50 cm.

2. 2. At the borehole base, the englacial feature showed large quantities of sediment (Figs 6b and c).

3. 3. The camera shook violently when positioned within the englacial feature and sediment was being transported at the base. Both observations indicate an englacial flow within the feature.

4. 4. The side camera did not provide any information on the size of the feature due to the poor visibility.

Fig. 6. Borehole camera observations within englacial feature. (a) GPR survey with boreholes overlaid and their respective depths shown. (b) and (c) Borehole camera images at the base of borehole 4 showing sedimentary debris within englacial feature.

Borehole water pressure

For the majority of the borehole campaign, the englacial water pressure appeared relatively constant during borehole camera recordings. When the camera was placed in BH3 and BH4, the water level was ~1–2 m above the englacial feature and we observed small changes (< 0.5 m) in the borehole water level indicating an englacial flow near atmospheric pressure. Permanent borehole water pressure sensors were not installed and therefore only water pressure observations were taken whilst using the borehole camera. On several occasions, we observed geyser-like events where englacial water was being blown from the top of the borehole for several minutes caused by a short-term increase in englacial water pressure.

Borehole results interpretation

Upon hydraulic connection to the englacial feature, the water within the BH3 and BH4 immediately drained providing evidence that this feature is not a water table. Additionally, we observed flowing water using the borehole camera and therefore it is not possible that such an englacial feature can accumulate water within the glaciers vein network. Based upon the borehole drilling campaign we reject the water table hypothesis and conclude that there is no evidence to suggest that the englacial reflection is caused by a water table.