2.2.1. Cooper–Bredehoeft method

Assuming that transient flow in a low-transmissivity aquifer is confined and cylindrical, occurring radially out of, and back into, the borehole face, the hydraulic head in the aquifer (h) is appropriately described by (Reference Cooper, Bredehoeft, Papadopulos and BennettCooper and others, 1965):

Here, S is the storage coefficient (the pore volume change per unit surface area of the glacier bed per unit head change) and r_A is the horizontal distance from the axis of the borehole filter. Equation (1) is based on the conservation of fluid volume, incorporating aquifer and fluid compressibility in the storage term, combined with Darcy’s law, thus neglecting turbulence and assuming a homogeneous aquifer.

The Cooper–Bredehoeft model is a particularly popular method for the analysis of overdamped slug-test responses in low-transmissivity, confined aquifers (e.g. Reference ButlerButler, 1997, p. 57). This method connects transient changes in hydraulic head in the aquifer (h(r_A, t)) with those in the borehole (H(t)), induced by slug insertion or withdrawal, considering continuity of water flow at the borehole face (where r_F = r_A) and neglecting water-column inertia:

The Cooper–Bredehoeft model assumes that well losses are negligible (h(r_F,t) = H(t) for t > 0), and that the slug is introduced or withdrawn instantaneously (h(r _A,0) = 0 for r_F < r_A < ∞; H(0) = H₀). It is also assumed that there are no flow boundaries within the portion of the aquifer influenced by the slug test (h(∞,t) = 0 for t > 0), and that elastic storage mechanisms, as expressed by S in Equation (1), affect slug-test responses. The Cooper–Bredehoeft model considers that

where

Here, β is the dimensionless time parameter and α is the dimensionless storage parameter. Reference Cooper, Bredehoeft and PapadopulosCooper and others (1967) and Reference Papadopulos, Bredehoeft and CooperPapadopulos and others (1973) plot H(t)H^¹ against the logarithm of β, resulting in a series of type curves characterized by different values of α. Matching of appropriately processed field data with the best-fit type curve allows estimation of aquifer transmissivity using a series of well-defined steps (e.g. Reference ButlerButler, 1997, p.58).

2.2.2. Guyonnet method

Since the Cooper–Bredehoeft model assumes that aquifers are unbounded, systematic deviations between observed slug-test responses and best-fit type curves often occur where flow boundaries exist within the portion of the aquifer influenced by slug tests (e.g. Reference Karasaki, Long and WitherspoonKarasaki and others, 1988; Reference Guyonnet, Mishra and McCord.Guyonnet and others, 1993). Subglacial aquifers at Alpine glaciers are notoriously heterogeneous (e.g. Reference Hubbard and NienowHubbard and Nienow, 1997), making the presence of flow boundaries within such portions likely. Constant-head and no-flow boundaries would, respectively, result in faster and slower WL recovery than predicted by the Cooper–Bredehoeft model (e.g. Reference Moench and HsiehMoench and Hsieh, 1985), representing a diagnostic means of their identification in a joint plot of observed response and best-fit type curve. Constant-head boundaries could be represented by water-filled subglacial channels or cavities, as discussed by Reference Iken, Fabri and FunkIken and others (1996) in a slug-test context, or by transitions from connected to unconnected regions of the glacier bed (section 1), which may hydraulically force each other (e.g. Reference Murray and ClarkeMurray and Clarke, 1995). No-flow boundaries could potentially result where subglacial sediment layers pinch off. Reference Guyonnet, Mishra and McCord.Guyonnet and others (1993) evaluate the analytical solution to the Cooper– Bredehoeft model (as summarized in Equations (3a–c)) to determine the distance between the tested borehole and constant-head or no-flow boundaries. The Guyonnet method thus promises to be well suited to identifying the nature and location of such boundaries in subglacial hydrological systems at Alpine glaciers.

Reference Guyonnet, Mishra and McCord.Guyonnet and others (1993) consider that any particular drawdown caused by a slug test will not travel beyond a certain distance (e.g. Reference SageevSageev, 1986), and focus on estimating this distance as a function of time, specifically allowing for storage in the test well, which may critically decrease the impact of a flow boundary on the response curve (e.g. Reference Karasaki, Long and WitherspoonKarasaki and others, 1988). Estimation of distance to the closest flow boundary uses a series of well-defined steps, based on a dimensionless formulation of the problem (Reference Guyonnet, Mishra and McCord.Guyonnet and others, 1993). Key to these steps are type curves representing functions of deviation between measured response curves and best-fit Cooper–Bredehoeft type curves, and of storage in the borehole.

2.3.1. Van der Kamp method

The Van der Kamp method connects a simplified version of Equation (4), ignoring the non-linear term, with Equation (1) to describe slug-induced flow in the borehole–aquifer system, thus being subject to their combined initial and boundary conditions. The damped-spring solution of classical physics is applied to the resulting governing equations. This solution is approximate, in that it is valid neither for the initial moments of the WL displacement (i.e. before the first sinusoid peak), nor for responses that are not well within the underdamped regime. If n is an index of iteration (n ≥ 1), this solution suggests that aquifer transmissivity (Tn) may be estimated from:

where

Equations (5a–d) use the notation of Reference Wylie and MagnusonWylie and Magnuson (1995), with ω and γ respectively representing the frequency and the damping constant of the induced WL oscillations. Reference Wylie and MagnusonWylie and Magnuson (1995) proposed a convenient spreadsheet approach for the implementation of the Van der Kamp method, which we adopt in the present study.

2.3.2. Kipp method

As outlined by Reference ButlerButler (1997, p. 159–163;a brief summary is presented here focusing on relevant aspects), general linear models have been developed to allow for any degree of damping, overcoming the limitations of the Van der Kamp method in this respect. Out of these, application of the type-curve approach included in the Kipp method has been particularly popular in field scenarios involving fully penetrating borehole filters. This approach conceptually considers the same analytical connection between flow in aquifer (i.e. using Equation (1)) and flow in the borehole (i.e. using an equivalent simplification of Equation (4)) as the Van der Kamp method, thus also being subject to their combined initial and boundary conditions. Suffice it to say that the key difference between the two methods is the mathematical solution to the simplified version of Equation (4), which in the Kipp approach allows for any degree of damping. This assumes that the magnitude of the dimensionless storage parameter (α_K; Equation (6b)) is small, and that the value of the inertial parameter (β_K Equations (6c and d)) is very large. The latter is related to the times of match between the measured response curve and the best-fit Kipp type curve through effective water-column length (L_e). After L_e, α_K and β_K have respectively been determined from Equations (6a), (6b) and (6c), the transmissivity (T) of the aquifer is estimated from Equation (6d):

Here, t_D is dimensionless time as used by the type curves, t is elapsed time of slug test, ζ is the damping factor and σ is a parameter expressing the significance of the borehole skin. Slug-test responses are respectively overdamped, critically damped and underdamped for ζ >1, ζ = 1 and ζ <1, and the Cooper-Bredehoeft solution applies for ζ > 5 where inertial effects become negligible (Reference KippKipp, 1985).

5.2.1. Determination of subglacial transmissivity

Reference Stone, Clarke and EllisStone and others (1997) stressed the importance of removing non-slug-test related trends in WL from the response data. We use an approach similar to theirs, which involves fitting a straight line through and subsequently subtracting it from our data. In addition, the data prior to the first peak of WL displacement are removed from oscillating slug-test responses to satisfy the assumptions involved in the Van der Kamp model and the conditions of the approximate solution (Reference KraussKrauss, 1974; Reference Van der KampVan der Kamp, 1976).

Following data preparation, curve matching is employed to derive natural frequency and damping constant by least-squares minimization of the misfit between measured and calculated responses. The match between prepared field data and calculated oscillations is excellent (see example in Fig. 6) for all 12 underdamped slug tests analyzed. Entering natural frequency and damping constant into Equation (5) typically results in convergence after three iterations based on a tolerance of 0.1%. Effective water-column lengths are calculated to be ~90m and ~128m for BH 95/69 and BH 95/75, which, respectively, are in good and fair agreement with the observed pre-test WLs of ~85 m and ~111 m. Assuming a storage coefficient (S) of 1 × 10^–4, which is a typical value for confined aquifers (Reference Freeze and CherryFreeze and Cherry, 1979, p.60), a borehole radius (r_BH) of 0.05 m, and a filter radius (r _F) of 0.25 m, we obtain transmissivity (T) estimates of 13.2 × 10^–3m²s^–1 for BH 94/69, and 5.7 × 10^–3m²s^–1 for BH 94/75.

Fig. 6. Application of the Van der Kamp method: matching of prepared field data (grey lines) and calculated oscillations (smooth black lines) for (a) BH 94/69 and (b) BH 94/75.

5.2.2. Sensitivity analysis

The transmissivities calculated in the previous section represent ‘best estimates’, assuming that (i) slug-test responses are perfectly repeatable, (ii) the least-squares fits between measured and calculated responses have a R² of 1 and (iii) previously reported values of the storage coefficient (S) and borehole (r_BH) and filter (r_F) radius also apply at Haut Glacier d’Arolla. In practice, however, some errors normally arise when repeating slug tests and fitting calculated responses, and both radii and the storage coefficient could be somewhat different at Haut Glacier d’Arolla than at other glaciers. In order to investigate the effect of these uncertainties on our transmissivity estimates, we conduct sensitivity analysis using the approach suggested by Reference Kulessa and MurrayKulessa and Murray (2003). Each of the six uncertain parameters (response repeatability, oscillation frequency ω), damping constant (γ), borehole radius (r_BH), filter radius (r_F) and storage coefficient (S)) is assigned an error range within the limits of reason. Each parameter is then varied individually within its given error range relative to the best estimates of the other parameters. The resulting six transmissivity ranges are then used to calculate an overall standard deviation.

The resulting variations in transmissivity are summarized in Table 2. Response repeatability and curve-fitting errors have minor impact on transmissivity compared to variations in the other three parameters (Table 2). Of the latter, borehole radius (r_BH) and the storage coefficient (S) have a particularly strong influence, causing transmissivity variations of almost one order of magnitude. Note that transmissivity is inversely related to filter radius (rF) and S. The standard deviation of the transmissivity range reported in Table 2 was calculated to be 5.2 × 10^–3 m² s^–1 for BH 94/69 and 2.4 × 10^–3 m² s^–1 for BH 94/75. We therefore conclude that the subglacial sediments at BH 94/69 and BH 94/75 have respective transmissivities of (13.2 ± 5.2 )x 10^–3 m² s^–1 and (5.7 ± 2.4)x 10^–3 m² s^–1.

5.3.1. Determination of subglacial transmissivity

The overdamped slug-test responses recorded in BH 95/1 and BH 95/14 were initially prepared in the same way as the underdamped responses (previous section), and subsequently fitted by exponential signal decays (e.g. Fig. 7a and b). During the first few seconds of a slug test, high-frequency fluctuations are often superimposed on the exponential decay (Reference Kulessa and HubbardKulessa and Hubbard, 1997). We ignore these fluctuations, in accordance with Reference Butler, McElwee and LiuButler and others (1996) who argued that such ‘fluctuations are related to test initiation and should be ignored when considering the quality of the match between the best-fit model and the test data’. All slug tests conducted in BH 95/1 produced a virtually identical match with the Cooper-Bredehoeft type curve for α = 10^–10. This type curve presented the best-fit choice, yielding t_C = 2.3 s for all four tests (Fig. 7c). With r_BH = 0.05 m, a transmissivity (T) of 10.6 × 10^–4m²s^–1 is obtained. An analogous procedure applied to the responses recorded in BH 95/14 yields t_C = 6.9s (Fig. 7d) and T = 3.6 × 10^–4m²s^–1 if r_BH = 0.05 m. These calculated transmissivities are consistently lower than those inferred from analysis of underdamped slug-test responses recorded in BH 94/69 and BH 94/75 (Table 2).

Fig. 7. Application of the Cooper-Bredehoeft method: prepared field data (grey lines) and exponential decays (black lines) for (a) BH 95/1 and (b) BH 95/14, and logarithmically transformed exponential decays characterizing (c) BH 95/1 and (d) BH 95/14 (black lines) matched with the Cooper–Bredehoeft type curve for α = 10^–10 (grey lines). t_C is the time of match in the Cooper– Bredehoeft method, and t _dev is the time of 1% deviation in the Guyonnet method. Sampling interval was changed to 5s where circles replace solid lines at later times in (a) and (b). Note that the abscissa label in (c) and (d) is equal to the dimensionless time parameter β (see Equation (3b)). W ₀ is initial WL displacement.

5.3.2. Determination of subglacial constant-head boundaries

In this study, the later portions of all measured responses lie below the best-fit Cooper-Bredehoeft type curve, implying faster recovery (Fig. 7c and d) and, thus, the presence of a subglacial constant-head boundary (Reference Guyonnet, Mishra and McCord.Guyonnet and others, 1993). The presence of such boundaries is consistent with the inhomogeneous nature of the subglacial drainage system in the study area (section 3.1). Based on our best estimates of transmissivity (T = 10.6 × 10^–4 m² s^–1 for BH 95/1 and 3.6 × 10^–4 m² s^–1 for BH 95/14), storage coefficient (S = 1.0 × 10^–4) and borehole radius (r_BH = 0.05 m), we obtain respective distances of ~5m and ~6.5m from the bases of BH 95/1 and BH 95/14 to the closest constant-head boundaries (Fig. 8) using figure 6 in Reference Guyonnet, Mishra and McCord.Guyonnet and others (1993). Both values appear reasonable considering the limited radius of influence of the slug-test method in general, and the heterogeneous character of the subglacial drainage system in the survey area in particular. Reference Hubbard, Sharp, Willis, Nielsen and SmartHubbard and others (1995) located the centre of a subglacial channel at an easting of ~606785, and BH 95/1 is located at 606787.5 (i.e. 2.5 m from the channel;Fig. 2c). We therefore believe that the inferred constant-head boundary near this borehole is probably associated with this preferential water-flow pathway. The origin of the constant-head boundary near BH 95/14, and indeed its subglacial hydraulic connection as such, is probably related to preferential seepage induced by water entering the glacier bed near the eastern margin, where crevasses and surface streams are common.

Fig. 8. Determination of dimensionless distance from dimensionless time and the borehole storage coefficient (after Reference Guyonnet, Mishra and McCord.Guyonnet and others, 1993, fig. 6). The dashed and solid arrows, respectively, reflect application of the Guyonnet method in BH 95/1 and BH 95/14.

5.3.3. Sensitivity analysis I: transmissivity

Using the same approach to sensitivity analysis as that used in the underdamped case (section 5.2.2), we found that neither repeatability of the response signals nor variations in the initial amplitude of the exponential decays altered transmissivity noticeably. The sole parameter introducing major uncertainty is borehole radius (r_BH), which may cause order-of-magnitude variations in transmissivity (Table 3). Together the transmissivity values listed in Table 3 produce a standard deviation of 3.7 × 10^–4m²s^–1 for BH 95/1 and 1.2 × 10^–4m²s^–1 for BH 95/14.

5.3.4. Sensitivity analysis II: distance to constant-head boundary

In the case of the Guyonnet method, uncertain parameters are (i) the time of 1% deviation between the exponential decay and the Cooper–Bredehoeft type curve (t_dev), (ii) transmissivity (T), (iii) borehole radius (rBH) and (iv) the storage coefficient (Table 4). Uncertainty (i) is small for BH 95/1 and negligible for BH 95/14 (Table 4), which suggests that graphical estimation procedures are relatively accurate. Variations in transmissivity and borehole radius typically result in metre-scale variations of distance to the closest constant-head boundary (Table 4), which together with the small graphical uncertainties would place reasonable error bounds on distance to the closest constant-head boundary (1.0m for BH 95/1;1.5m for BH 95/14). However, unfortunately the storage coefficient has an overwhelming impact on this distance (Table 4). A storage coefficient of the order of 10^–2–10^–3, as previously reported for unfrozen marine sediments beneath Bakaninbreen, Svalbard (Reference Porter and MurrayPorter and Murray, 2001), produces an unrealistically small distance (^1 m). In contrast, a storage coefficient of the order of 10^–7, as previously reported for Gornergletscher, Valais, Switzerland, based on slug tests (Reference Iken, Fabri and FunkIken and others, 1996), causes distance to reach 14.5m for both BH 95/1 and BH 95/14 (Table 4), which is not unrealistically large (e.g. Reference ButlerButler, 1997, p.183). Inclusion of the latter increases the standard deviation of the distance to the boundary to 2.9 m for BH 95/1, and 2.3 m for BH 95/14. Note that distance is inversely related to borehole radius (r_вн) and the storage coefficient (S).

5.3.5. Summary

Analysis of overdamped slug-test responses reveals that BH 95/1 is underlain by unconsolidated sediments that have a transmissivity of 10.6 ± 3.7 × 10^–4m²s^–1. The base of this borehole is located 5 ± 2.9 m from the closest subglacial constant-head boundary, which probably corresponds to the subglacial channel detected by previous authors (section 3.1). The sediments beneath BH 95/14 have a transmissivity of (3.6± 1.2)x 10^–4m²s^–1, and its base is located 6.5 ± 2.3 m from the closest constant-head boundary. The latter is probably associated with water entering the glacier bed at the eastern margin. It is unlikely that the subglacial storage coefficient (S) is larger than ~10^–4 at either borehole since unrealistically small distances to constant-head boundaries would result.

5.4.1. Determination of subglacial transmissivity

The Kipp method promises to allow both identification of critically damped response signals, and estimation of subglacial hydraulic properties. Data are initially prepared in the same way as underdamped slug-test data (section 5.2.1). The match between all four repeat tests in BH 95/16 and the Kipp type curve for ζ = 1.5 is very good (Fig. 9). The test responses in this borehole are therefore just overdamped, although the Cooper–Bredehoeft solution does not apply since inertia is still significant (section 2.3.2). Using a filter radius (r_F) of 0.25 m, a storage coefficient (S) of 1.0 × 10^–4, and an effective water column length (L_e) of 23.1 m as measured at the time of testing, Equation (6d) yields a transmissivity (T) of 4.7 × 10^–3 m²s^–1.

Fig. 9. Application of the Kipp method: matching of prepared field data (black circles) with the Kipp type curve for ζ = 1.5. W₀ is initial WL displacement.

5.4.2. Sensitivity analysis

Similar to the overdamped case (section 5.3.3), repeat slug tests were found to produce negligible transmissivity variations (Table 3). Both borehole (r_BH) and filter (r_F) radii have an impact of up to approximately one order of magnitude on transmissivity estimates, transmissivity being inversely related to r_F and the storage coefficient (S). Reducing the latter from 1.0 × 10^–4 to 1.0 × 10^–7 approximately doubled the transmissivity estimate, while the Kipp inertial parameter (/3_K), and thus transmissivity (Equation (6d)), could not be calculated for S < 10^–4 (Table 3). This agrees with previous conclusions based on application of the Guyonnet method to the overdamped slug-test responses (section 5.3.4), and therefore confirms that the subglacial storage coefficient is unlikely to be larger than this value.

We conclude that the sediments below the base of BH 95/16 have a transmissivity of (4.7 ± 4.0) x 10^–3 m² s^–1, and that the subglacial storage coefficient (S) in our study area is probably of the order of 10^–4 or smaller.