Abrasion—observations

Abrasion is accomplished by rock and mineral debris embedded in the glacier sole and in traction over the bed. There are now many observations of the nature of this basal debris and its motion over the bed (Reference PetersonPeterson, 1970; Reference Boulton and CoatesBoulton, [^c1974], Reference Boulton1978; Reference Boulton, Boulton, Morris, Armstrong and ThomasBoulton and others, 1979; Reference VivianVivian, 1975). Large clasts in traction are retarded relative to the ice and often have cavities in their lee. Particles of different size and shape move with different velocities. Because of this, particle collisions are frequent and relatively dense particle assemblages frequently build up. Some particles slide, others roll, depending on their shape. Considerable comminution is produced at the interface between large clasts and the bed, which results in production of fine sand and silt rock flour, and may be the single most important global source of silt.

A study of the concentration of particles in basal ice was made in natural cavities and artificial tunnels beneath Breiðamerkurjökull in Iceland. A plan of the volume concentration of debris in the exposed basal ice is shown in Figure 2c. In the centre of cavity B, the concentration in the basal 10 cm of ice measured from c. 800 cm³ samples was 8–10% by volume. The thickness of the debris-rich horizon was between 5 and 20 cm. On the eastern side of the cavity, and emanating from a longitudinal trough in the glacier bed, the concentration of debris in similar-sized samples of basal ice was substantially higher, 15–20% by volume. The thickness of the debris-bearing horizon was also greater, being up to 1 m thick. In an attempt to determine the origin of this higher debris concentration and greater thickness of the basal transport zone, which was also clearly noticeable on the flanks of cavity A, a tunnel was constructed over the up-glacier side of the rock hummock. The directions of the freshest striae, which give an indication of the latest movement of clasts embedded in the glacier sole, were measured on accessible bedrock surfaces (Fig. 2b). This showed a strong flow convergence towards the trough produced by a transverse component of flow around the proximal extremity of the rock hummock up-glacier of cavity B. Such a convergence will clearly be stronger near to the glacier sole and diminish in strength upwards. This will not only tend to thicken the debris-rich horizon in the trough but, as the debris concentration tends to be greatest in the lowest part of the basal transport zone (cf. Reference Boulton, Boulton, Morris, Armstrong and ThomasBoulton and others, 1979), and this undergoes greatest lateral flow, the concentration of debris in the trough will also tend to be greater than in the ice moving over the summit of the hummock. Two other important effects are also likely to enhance the debris concentration in the glacier sole in the trough. First, transverse compression and vertical extension will decrease interparticle distances in the plane of the glacier sole. Secondly, net melting at the glacier sole will tend to concentrate debris there, an effect which would be expected to be greatest in troughs because of: (a) a greater geothermal heat flux there (Reference Nobles, Weertman and GoldthwaitNobles and Weertman, [^c1971]), (b) preferential flow of water in furrows (Reference WeertmanWeertman, 1972), (c) greater frictional melting due to greater debris concentration in the glacier sole.

Fig. 2. Observations in natural cavities and artificial tunnels beneath the western ṁargin of Breiðamerkurjökull, Iceland, at the beginning of the experiment.

• (a) Contours on bedrock showing two well-defined roches moutonnées. T₁–T₄ are the locations of stress transducers and abrasion experiments.

• (b) Flow lines of basal ice measured from grooves in the glacier sole in natural cavities, and freshest striae on the floors of tunnels. Note the divergence around the stoss sides and convergence on the lee sides of the two hummocks.

• (c) Debris concentrations in the basal 10 cm of ice. The observed concentrations are explicable in terms of “streaming” around the hummocks.

• (d) Long profiles over the two roches moutonnées. Note the folds at the points of cavity closure. Till occurs against the steepest point of the bedrock surface near ϒ where greatest normal pressures can be expected. Normal pressure at T₄ was 23.5–24 bar. According to the theory (Fig. 4b), the threshold for deposition is 31 bar.

• (e) Transverse profiles on the east side of the bedrock hummocks. The grooves coincide with relatively debris-rich “streams” of basal ice.

I suggest the term “streaming” for the flows which produce concentration of debris-rich ice in low points of the glacier bed, and further suggest that this process is largely responsible for the pattern of debris concentration in basal ice shown in Figure 2c.

On the eastern flanks of both the bedrock hummocks shown in Figure 2 there are major grooves parallel to ice flow and 1–2 m in width which can be seen in the cross-sections in Figure 2e. The grooves shown in profile through T₁ and T₃ have very sharply defined margins. The concentration of debris in the glacier sole above these grooves is markedly greater than in inter-groove areas. I suggest that this reflects the processes associated with streaming of debris-rich basal ice into the groove. Assuming that normal pressures and velocities are roughly similar in the grooves and inter-groove areas, the higher debris concentration in the grooves should lead to higher abrasion-rates there, thus deepening the grooves, and further enhancing streaming of debris-rich basal ice into them. Presumably, this will continue until “bridging” across the groove decreases pressure in it so as to decrease the abrasion-rate.

A theory of abrasion

Laboratory experiments investigating the mechanisms of wear along shearing interfaces (e.g. Reference Bowden and TaborBowden and Tabor, 1950; Reference Scholz and EngelderScholz and Engelder, 1976) suggest that a theory of glacial abrasion should be of the form:

where Ā is the abrasion-rate of the bed, c is the concentration of abrading particles in the ice, N is the effective normal pressure at the particle/bed contact, V _p is the velocity of the particles and h is the hardness of the bed.

Observations clearly show that particles in traction over the bed are retarded relative to the moving ice. Reference Boulton and CoatesBoulton ([^c1974]) attempted to assess particle velocity in two ways: first, by adapting Reference WeertmanWeertman's (1957) theory of glacier sliding by replacing fixed cubic obstacles by moving cubic debris particles retarded relative to the basal ice by friction against the glacier bed, and secondly by assuming that rigid debris-rich masses were built up in the basal ice, and using Reference NyeNye's (1970) sliding theory to determine the relative velocity over its rough upper surface produced by a given frictional resistance of the bed. Using the first approach, the velocity of the particle over the bed was:

where V _i is the velocity of basal ice, B a constant in Glen's flow law, l the diameter of the clast, μ the coefficient of friction between clast and bed, A ₁ the apparent area of contact between clast and bed, A ₂ the area of the clast in the transverse plane, C a coefficient relating pressure and the melting point of ice, L the latent heat of ice, and K the thermal conductivity of ice.

An attempt to test this theory was made at the site beneath Breiðamerkurjökull shown in Figure 2. The techniques employed have been described in previous papers (Reference Boulton and CoatesBoulton, [^c 1974]; Reference Boulton, Boulton, Morris, Armstrong and ThomasBoulton and others, 1979). A ₁, and A ₂ (Equation (2)) were measured for different values of l for a basal debris assemblage from Breiðamerkurjökull, for which it is assumed that particle long axes lie parallel to flow, and values of μ were derived from shear force/normal pressures recorded by the transducer array shown in Figure 2 during the passage of individual clasts. Theoretical values of V _p were then determined for the whole grain-size range for different values of N (Fig. 3a). Actual velocities of particles of known size and shape can be inferred from their passage over the transducer array shown in Figure. 2. The transducer measures eccentricity of load which has a maximum positive value when the centre of gravity of a clast first moves on to the transducer, and a maximum negative value immediately before it leaves. The time interval between maximum and minimum values allows clast velocity to be estimated. The transducer also gives values of effective pressure on the ice/bed interface (Reference Boulton, Boulton, Morris, Armstrong and ThomasBoulton and others, 1979). These values are plotted in Figure. 3a where they show a similar trend to those predicted by the theory. Velocities at T₂ and T₄ are underestimated. I suggest three principal reasons for this. First, some clasts may have had cavities in their lee when they moved over the transducer. Secondly, the theory assumes no friction against the sides of the clasts, and thirdly, it is clear that interactions between particles travelling at different velocities are likely to have a strong influence upon individual particle velocities.

Fig. 3.

• (a) Graphs show theoretical values of particle velocities for different values of effective normal pressure and grain-sizes from 1 mm (oφ) to 512 mm (—9φ). The irregularities of the curves reflect changing mean values of the shape parameter A₁/A₂ for different grain-sizes. Theoretical and observed values of particle velocities are shown. Mean values of normal pressure at T₁, T₂, and T₄ are 7.8, 16.4, and 23.5 bar, respectively.

• (b) Grain-size distribution for particles between 0φ and – 9φ.

The maximum predicted particle velocities occur in the grain-size range — 7φ (128 mm) to — 3φ (8 mm), which are thus equivalent to Reference WeertmanWeertman's (1957) controlling obstacles, being the grain-size around which ice has the greatest difficulty flowing. An observed peak in particle velocities occurs between 7.5 and 23.5 bar. Where debris concentrations are relatively large, particle interactions may clearly be very important. The most rapidly moving particles of intermediate size are likely to be slowed down both by larger and smaller particles. Though this effect would act in an opposite sense to the others considered above, it clearly does not entirely counteract them, and velocities are still underestimated.

In order to produce a readily manipulable abrasional theory, it would be useful to derive some estimate of the average velocity of the particle assemblage, or at least that of the coarsest end of the grain-size spectrum which does most abrasional work. In the particular case of the debris in Figure. 3b, I propose to use the velocity of —7φ particles as an index of the velocity of the whole debris assemblage, as it is the class that has the largest volumetric representation in the grain-size distribution. Variations in values of V _p for this size class for different values of N and the range of velocities measured beneath Breiðamerkurjökull are shown in Figure. 4a.

Fig. 4.

• (a) Velocity of — 7ϕ (128 mm) particles of mean shape from Breiðamerkurjökull plotted against effective normal pressure for an ice velocity of 15 m year^–1.

• (b) A curve showing relative abrasion-rates for changing effective normal pressure and an ice velocity of 15 m year^–1. Measured abrasion rates for three sites (T₁, T_2, and T₄) and for plates of different material are plotted. The measured abrasion-rate for marble at site T₁ was plotted on the theoretical Curve, and other points normalized. Till had accumulated up-glacier of site T₄ where the normal pressure was probably somewhat greater than 24 bar. According to the theoretical curve, lodgment should commence at 31 bar. (Measured hardnesses were: aluminium 50–60 kg mm^–2; limestone 180–215 kg mm^–2; marble 450–510 kg mm^–2; slate 605–660 kg mm^–2; basalt 865–905 kg mm^–2.)

If we take V _p(–7φ) as a reasonable index of the mean velocity for the whole debris assemblage, then an abrasion-rate can be calculated from Equations (1) and (2):

Dimensionless abrasion-rates for measured values of the mean A ₁/A ₂ at l = —7φ and for V _i = 15 m year^–1 are shown in Figure 4b.

Net abrasion-rates were measured at a number of points on the bedrock surface shown in Figure 2 by measuring the mean reduction in thickness of rock plates (10 cm by 5 cm) of different hardness after they had been attached, flush with the bedrock surface, for 14 months (431 d). Sliding velocities of 14.9 m/year were directly measured at the beginning of the experiment (April), of 19.2 m/year at the end (July), and indirectly by bore-hole and inclinometer surveys in September (13.6 m/year), January (11.2 m/year), and April (12.5 m/year). A mean velocity of 15 m/year was assumed. Normal pressures at each site were measured by transducers for 4 d at the beginning and end of the experiment. Mean pressures were smaller at the end of the experiment than at the beginning, presumably because of glacier thinning during retreat. The maximum pressure reduction, of 4.3 bar, was measured at T₃. Our uncertainty of the precise form of pressure fluctuation for the whole period of the experiment could be a large source of error, although there was nothing unusual about the external behaviour of the glacier, which was frequently monitored during this period. I do not expect large errors to stem from the assumption of a mean pressure value.

At the end of the experiment, the ice which had passed over each transducer during the 14 month period was sampled and debris concentrations measured. These showed little variation, apart from that produced by occasional large boulders.

As might be expected with the relatively crude physical approximations of the theory and the potential errors of measurement, measured rates do not give a good quantitative fit to the theory. However, the measured data are compatible with an extremely important prediction of the theory, that for a constant ice velocity, abrasion-rates will first increase, and then fall with increasing effective pressure. For this site, predicted values of abrasion-rate peak at 20.9 bar whilst measured values suggest a peak between 7.5 and 23.5 bar, which can probably be more closely estimated as between 16.25 and 23.5 bar.

The theory is not only a theory of abrasion but also a theory of deposition. The two form a continuum in which abrasion occurs when the tractive force of the moving ice is adequate to maintain clasts in motion and deposition occurs when it is not, which in Figure 4b is when V _p = 0. This suggests that deposition might occur where pressures are very high on the up-glacier flanks of roches moutonnées. The prediction is supported by observations beneath the glacier, up-glacier of cavity B, where deposition of till appears to have occurred at a point where normal pressure values were probably somewhat greater than the mean of 23.5 bar measured at transducer T₄. This is also supported by observations in the pro-glacial area, where till is frequently plastered against the steepest part of the up-glacier faces of roches moutonnées.

The rock and metal plates which have been used to determine abrasion-rates have been attached to bedrock in longitudinal series and have therefore undergone a similar erosional history. Abrading clasts are predominantly basalt, and a linear relationship has been found between abrasion-rate and I/h for plates of limestone, marble and slate. However, this ratio is significantly smaller for basalt plates and relatively variable for granite plates. I suggest that the variability of the abrasion-rate for granite reflects its relative inhomogeneity. It contains large crystals of quartz and feldspar, and some of the wear clearly reflects pulling out of individual crystals. I suggest that the low measured rates for basalt reflect a situation reported in laboratory experiments where asperities whose hardness is less than 1.2 times the hardness of the surface (flat) over which they are moving do not plough through it, but that fragments of the asperity adhere to the flat (Reference Bowden and TaborBowden and Tabor, 1950; Reference Engelder and ScholzEngelder and Scholz, 1976). However, the interface between a clast in traction and the glacier bed cannot be simply characterized as asperity and flat. Either surface may locally be asperity or flat, and thus clasts and beds of similar lithology probably break down at similar rates. Microscopic studies of the striae left on the experimental plates suggest that ploughing, adhesion, and stick-slip behaviour all occur using the criteria suggested by Reference Engelder and ScholzEngelder and Scholz (1976).

Modelling two-dimensional bedforms

The abrasional theory embodied in Equation (3) can be used in conjunction with a sliding theory which predicts the pressure distribution over a transverse ridge of low slope for a given constant velocity to predict the way in which the form of the ridge will change with time. This was done by Reference Boulton and CoatesBoulton ([^c1974]) using a slightly different abrasional theory in which basal debris-rich ice was assumed to behave in a more or less rigid fashion.

However, a two-dimensional bed is rare except where a rock series displaying interbedded units of strong hardness contrasts strikes normal to the direction of glacier flow. Most bedforms also violate the low-slope restriction of existing sliding theories. Nonetheless, this treatment seems to give a reasonable qualitative approximation to the longitudinal profiles of many glaciated hummocks and ridges (Fig. 5). The normal-pressure distribution over the sinusoidal cross-profile of a ridge elongated transverse to flow was computed for a constant ice velocity parallel to its surface using Reference NyeNye's (1970) sliding theory. This was done for two values of ice-overburden pressure which were selected so that the range of pressure over the ridge lies (a) entirely to left of the peak in the abrasion-rate curve (Fig. 4b), (b) entirely to the right of the peak. The lowering of the surface by abrasion was then computed. The pressure distribution over the new bedform was then re-computed and the process repeated. By a series of such steps the progressive evolution of the form of the bed was followed (Reference Boulton and CoatesBoulton, [^c1974].

Fig. 5a and b. Modelling the evolution of two-dimensional abrasional bedforms, showing the influence of different ranges of normal pressure On the resultant forms. Numbers of computational steps in each form are shown.

In case (a), maximum abrasion-rates are initially concentrated at the steepest point of the up-glacier slope and at the foot of the down-glacier slope. Because of this, and the existence of a cavity on the down-glacier flank, the form becomes asymmetric but is finally reduced to a step with a basin on its down-glacier side. This is a particularly interesting prediction in view of Reference LewisLewis's (1947) demonstration of a continuous gradation from roches moutonnées to valley steps. In case (b), maximum abrasion-rates are concentrated on the down-glacier side and deposition rather than abrasion occurs on the up-glacier side. The form becomes asymmetric but in the opposite sense to case (a). In case (a), the form develops down-glacier asymmetry, like a classical roche moutonnée, and its summit migrates in the same direction. In case (b), the form develops up-glacier asymmetry, like a classical drumlin, and its summit moves in that direction. In case (b), it is possible that a considerable accumulation of till on the up-glacier flank might change its shape considerably. In case (a), till might be expected to accumulate in the cavity.

It is unlikely that subglacial conditions will ever remain sufficiently stable to allow these two trends to be perfectly followed. However, it is reassuring that the theory can simulate three common subglacial bedforms: roches moutonnées with a down-glacier asymmetry, steps with depressions in their lee, and drumlin-like forms.

Evolution of a three-dimensional rock bed

Glaciated bedrock surfaces are normally strongly ribbed, furrowed, and streamlined parallel to the direction of glacier movement (Fig. 1). How does a glacier achieve this when it moves over an area of hitherto unstreamlined bedrock? Consider a surface on which there are a series of randomly distributed bedrock hummocks and over which the glacier flows at roughly constant velocity. Differential abrasion of the surface will occur because of changes in normal pressure, ice velocity, and debris concentration. Unfortunately, there is as yet no theory which allows us to estimate pressure and velocity changes around a three-dimensional hummock, and thus I shall develop a qualitative argument about the role of changing debris concentration.

It has been suggested that the flow of basal ice around hummocks tends to concentrate debris-rich ice around the flanks (Fig. 2). Both debris-rich flanking ice and debris-depleted over-riding ice flow into the lee position, but it is clear that there will be residual lateral contrasts in debris concentration producing a net “streaming” (Reference Boulton and CoatesBoulton, [^c1974]). In effect, the bedrock hummocks produce a shadow zone in which the debris concentration is lowered and abrasion-rate is reduced. This streaming effect will clearly tend to enhance relief by a positive feedback in which the cutting of grooves due to the greater abrasion-rate is produced by debris streams concentrates even more debris, and I suggest that it may be the prime agent at work in producing large-scale lineations on bedrock surfaces. If there is a strong lateral flow of flanking ice into the lee position, then the streaming effect will be minimized and shorter, elongated bedforms will be produced. If the lee position is primarily filled by over-riding ice, the streaming effect will be greatest and bedforms will be relatively elongated. I would expect high pressures and low velocities to favour the first case and low pressures and high velocities to favour the second.

Just as original topographic irregularities can lead to streaming and the progressive development of a well-lineated surface, areas of harder rock can play precisely the same role. Limestone is frequently found to develop regular ridges and grooves of great longitudinal extent (e.g. Fig. 1a). I suggest that this might occur because of the tendency for many limestones to be very homogeneous. However, infrequent hard nuclei, such as cherts or silicified fossils, abrade less rapidly, and thus form upstanding knobs which produce streaming. The homogeneity of the limestones then allows long ridges and troughs to develop, whilst the original nuclei may be abraded away, though leaving the inherited knob which is the source of the streaming. Less homogeneous rocks produce elongated features which lack great continuity (Fig. 1b).

Processes

On the basis of the characteristics of some of the lodgement tills progressively exposed beyond the retreating margin of Breiðamerkurjökull in Iceland, it was suggested (Reference Boulton, Boulton, Dent and MorrisBoulton and others, 1974) that the upper part of the till underwent continuous deformation beneath the glacier. Several experiments were undertaken to establish if this indeed occurred. An experiment which finally produced unequivocal evidence of subglacial deformation was undertaken during 1977–78. A tunnel system was dug in the ice about 1–2 m above the glacier sole (Fig. 6) and probes were inserted into the underlying till at several points. The probes consisted of a series of contiguous annuli which fitted around a central rod and which could be detached by a counter-clockwise turn. The probe was inserted to depths varying from 0.6 to 0.85 m where boulders in the till allowed it, and the central rod was withdrawn. The narrow access holes were then sealed off using wooden plugs. After a period of 10 d the till was partially drained by pumping. The annuli were carefully excavated and their positions plotted. Water pressures had been measured by piezometer at each site during the experiment, and the form of the glacier/bed interface plotted using probes. The full experiment will be described elsewhere.

Fig. 6.

• (a) Map of part of the western ice margin of Breiðamerkurjökull, showing a plan of the tunnels and the positions of successful subglacial probes (A–G).

• (b) Section along the line of the principal tunnel and the profile of the glacier/till interface established by probes. The tunnel floor lies 1–2 m above the glacier sole.

Figure 7 shows the results at one site. About 90% of the total basal movement of the glacier is contributed by deformation of the bed materials and only 10% by slip between the glacier sole and till surface.

Fig. 7. The position of individual annuli at locality A, 244 h after their original emplacement in the position shown. 90% of the forward movement of the glacier sole is accounted for by deformation of the till. Boulders clearly strongly influence the pattern of deformation. The discharge of till at this site is 1122 cm³/cm in 244h.

It was possible to measure not only the net discharge of till at each site beneath the glacier but also the mean direction of movement of the till mass. It was found that a constant till discharge was not maintained along a glacier flow line. If we assume that the till is relatively incompressible on such small time scales, we must conclude either that there are locally strong vertical movements of the ice/till interface, which is not generally supported by repeated surveys of the ice/till interface (determined by probing), or that a lateral component of till flow occurs. This latter explanation is supported by measurements of the net movement direction of till which is not necessarily parallel to the direction of movement of the glacier sole and flutes at the glacier/till interface. Figure 8 gives a simple explanation of the observed rates of discharge per unit width, and flow directions, assuming an incompressible till and a stable glacier/till interface. It is interesting to note that the zone of converging flow is a relatively low area and the zones of diverging flow are relatively higher areas. The surface immediately beyond the glacier margin consists of low-relief drumlins with flutes on their surfaces. It seems likely that the subglacial forms determined by probing are parts of two drumlins separated by a broad furrow.

Fig. 8. Plan position of localities (A–G) at which subglacial deformation of till was measured. The measured directions of discharge and the direction of movement of the glacier sole are shown. The simplest contouring of lines of equal discharge per unit length has been produced. The flow lines required to produce this pattern of discharge have been determined, assuming a constant thickness of the deforming layer, on incompressible till, and no vertical movement of the glacier/till interface. The zone of converging flow is a broad furrow between two ridges which are co-axial with muted drumlins in the pro-glacial area, and which pass under the glacier margin. It is important to note that flow of till occurs across the axes of flutes, which are parallel to the measured direction of movement of the glacier sole.

At several sites now exposed beyond the margin of Breiðamerkurjökull there are stratified sediments which have been folded subglacially, presumably by the processes described above. The folds have flat-lying axial planes with synclinal axes pointing up-glacier and highly-attenuated anticlinal fold closures. It has sometimes been presumed that deformation of an unfrozen stratified sediment beneath a glacier would lead to destruction of that stratification. This does not happen, either for frozen or unfrozen sediments. Indeed, it is difficult to see how the independent particle motions required to destroy stratification could be achieved.

Implications for glacial erosion and landform development

If the process described here is widespread, it is a very powerful process of glacial transport and potentially able to accomplish extremely rapid geomorphic results. The rate at which mineral material is discharged by this process is at least ten times faster than the rate of discharge of debris in the basal ice and 200 times faster than debris discharge in the medial moraines of Breiðamerkurjökull.

The internal frictional and cohesive resistance to movement in the till is overcome by the shear force generated by movement of the glacier. The shear strength of the till can be described by a simple Coulomb law:

where C is the till's cohesion, φ its angle of internal friction, P the ice pressure, and P _W the water pressure. At the site shown in Figure 7, the internal frictional resistance of the till ((P— P _W) tan φ) is low. However, it has been determined experimentally (Reference Boulton, Boulton, Dent and MorrisBoulton and others, 1974) that near the snout (P—P _W) increases in an up-glacier direction, and a theoretical analysis (Reference Boulton, Boulton, Dent and MorrisBoulton and others, 1974) suggests that this increase is maintained towards the glacier source. Thus the strength of the till can be expected to increase progressively in an up-glacier direction and at some point the drag force imposed by the moving glacier will be insufficient to cause deformation of the bed. If the glacier front were to remain stationary, the effect of this process would be to create a sub-marginal depression parallel to the ice front. If retreat of the glacier were irregular, depressions would develop where glacier retreat was relatively slow. Breiðamerkurjökull has retreated about 4 km during the last 90 years, and from time to time the retreat rate has been relatively slow. During such periods, push moraines are formed, and behind groups of such moraines it is common to find broad depressions. This phenomenon has been widely identified in areas of Quaternary glaciation (e.g. Reference Jelgersma, Breeuwer, Zagwijn and van StaalduinenJelgersma and Breeuwer, 1975).

It is difficult to avoid the conclusion at Breiðamerkurjökull that the drumlinoid surface beyond the glacier must be related to the powerful transporting processes which occur beneath it. Indeed, the movement of material beneath the glacier seems to be geometrically related to the subglacial continuations of pro-glacial drumlins (Fig. 8). The till at Breiðamerkurjökull contains a large proportion of coarse particles, many up to 1–2 m in diameter. Observations at the surface show that these are not randomly dispersed but tend to be clustered (Reference Boulton and Jones PaulBoulton and Paul, 1976). If such a material deforms beneath the glacier, the coarser parts will tend to deform less rapidly than other parts, will block movement of material on their up-glacier sides, and thus produce transverse flow components, and provide a shadow-zone in their lee in which material will be relatively protected from deformation. Thus they will tend to generate long streamlined drumlins. If we presume the original inhomogeneities to have been randomly distributed, drumlins will tend to show an average spacing dependent upon the number of drumlin nuclei per unit area, and may coalesce. The drumlins will represent areas of net accumulation and the inter-drumlin zones areas of net erosion. Irregularities on the sub-sediment bedrock surface may play precisely the same role in blocking deformation and nucleating drumlins as inhomogeneities in the deforming sediment.

This process is potentially a very powerful agent of geomorphic work. It might occur deep beneath a glacier where high water pressures produce relatively small effective pressures (P—P _W) and thus low sediment strength. But it will always tend to operate in the marginal zone of temperate glaciers, and thus pre-existing drumlins formed deep beneath the glacier surface will tend to be substantially and rapidly modified beneath the glacier margin, and their final form will reflect conditions there. It is common to find drumlins emerging from beneath the retreating margins of modern glaciers, and in my experience they invariably reflect the direction of flow in the marginal area, testifying to the rapidity of modification in that zone.

I do not suggest that the process of drumlin formation proposed here is the only drumlin-forming process, but I do suggest that it is potentially the most powerful. It is similar to the process proposed by Reference Smalley and UnwinSmalley and Unwin 1968) in the respect that it requires deformation of the glacier substratum, but it does not require that the substratum be dilatant as they suggested.

Reference Shaw and FreschaufShaw and Freschauf (1973) (also Reference ShawShaw (1975) and Reference AarioAario (1977)) have proposed another mechanism for drumlin formation whereby helical flows are set up in the ice, which cause thick debris-rich ice zones to build up above the zones of flow convergence, which on melting out produce drumlins. The process proposed here sees the role of glacier and bed quite differently. The bed is soft compared with the glacier, and therefore deforms more readily. The bed is also less homogeneous than the glacier and thus differential deformation and lateral flow take place more readily in the bed, leadingto the production of streamlined landforms on the shearing interface.

Drumlins and mega-flutes exposed beyond the retreating margins of modern glaciers invariably have flutes on their surfaces, which show little deflection when followed over those surfaces. The flutes, which were formed in grooves in the glacier sole, must reflect flow lines on the glacier sole. The observations at Breiðamerkurjökull show that lateral flow of till across the trend of flutes can occur, and therefore across the flow lines in the glacier sole. It is difficult to see how the helicoid flow process could have drumlin-producing cells which cross the glacier flow lines marked by flutes.

The threshold for deformation and the rate of deformation of fine-grained sediments (e.g. Reference RoscoeRoscoe, 1952) are very sensitively dependent on pore-water pressures or small changes in grain-size distribution and mineralogy. The precise sequence of beds along a flow line beneath the glacier plays an important role in governing pore-water pressures (Reference Boulton and Jones PaulBoulton and Paul, 1976). Thus, if that sequence is changed by an advance or retreat of the glacier margin, pore-water pressure can change dramatically. Changes in pore-water pressure can also be produced by addition or loss of surface water to the subglacial aquifer. Increases in mass balance, which increase the basal shear stress, may also cause hitherto stable sediments to deform or deforming sediments to flow more rapidly. Thus the dynamic equilibrium of glaciers resting on beds of fine-grained sediment may be very unstable, and surging behaviour might result. A possible example of a glacier surge caused by a deformable water-soaked subglacial bed has recently been documented by Reference Mokievsky-ZubokMokievsky-Zubok (1978).

Direct observations

Wright Lower Glacier in Wright Valley, Victoria Land, Antarctica, has over-ridden a series of wind-blown sand dunes. The glacier margin, like many in this area, is vertical, and along the northern frontal and lateral margins the contact between the glacier sole and the underlying sediments is clearly exposed. The sediments comprise fine- to coarse-grained well-bedded sands. In places where they are relatively undisturbed, small-scale cross-bedding and rippled bedding can be found. Active dunes beyond the margin of the glacier give some indication of the state of the sands before they were over-ridden. The dune sands are cemented by ice, and the voids generally have a high saturation of above 70–80%, though some strata have as little as 20% void saturation. There are also many ice layers interbedded in the sands. The dunes originally formed from a mixture of blown sand and blown snow, and the ice in them represents metamorphosed snow. The varying ice concentration reflects the varying contribution of snow to the dunes, though sand predominates, partially because of the low annual precipitation of snow (c. 6 g cm^–2 year^–1) and partly because of sublimation of snow and ice. On inactive surfaces there is normally a layer of ice- and snow-free sand, which I presume to reflect loss of snow and ice due to sublimation in the very dry atmosphere.

The glacier/sand interface is relatively smooth with occasional hummocks 1–3 m above adjacent troughs. Several of these clearly represent original dunes. The frozen sand is heavily fractured in places, especially near the crests of hummocks, and sub-surface voids are common (Fig. 9a). In places, angular discordance of bedding across joint planes indicates that block rotation has occurred (Fig. 9a). Some of the interbedded ice strata have in places flowed along joint planes and into voids as diapiric masses. Disturbance of rippled beds and cross stratification indicate that flow of frozen sand has also occurred, although the style of folding is difficult to reconstruct.

Fig. 9. Deformed masses of aeolian sand beneath Wright Lower Glacier, Wright Valley, Victoria Land, Antarctica.

• (a) Detached and rotated blocks lie within the basal ice. The substratum is fractured, with voids and intrusions of glacier ice within it.

• (b) Presumed original location of a block that has now been detached and transported away (plucked). Sandy laminae within the ice are derived from the bed.

Masses of frozen sand have been incorporated within the glacier and occur up to 2 m above the bed. These may be cuboidal masses which are probably joint-bounded blocks plucked from the substratum, or lenticular or sheet-like masses (Fig. 9). These latter may have been attenuated by deformation in the ice, or they may have been plucked from the bed in that form. No unequivocally original sedimentary structures were observed in them, which may be evidence that they have been attenuated by flow.

There are also numerous disaggregated sand grains in the ice which are clearly derived from the bed. These may represent individual grains incorporated by the same process as the larger aggregated masses, or the latter's sheared-out remnants.

There are three important conclusions to be drawn at this site:

• (1) The frozen sediment bed has deformed both by fracture and flow.

• (2) Masses of sediment have been plucked from the bed without disaggregation.

• (3) The flow process has taken the sediment masses several metres above the bed, and the underlying ice does not represent regelation ice or ice formed from subglacial water.

Discussion

I suggest that the apparent ease of plucking at this site reflects two things: first, the adhesive bond between the glacier and frozen-bed sediments, which are thus subjected to a high tractive force that is probably enhanced by the much greater small-scale roughness of a bed composed of spheroidal grains compared with smooth bedrock (Reference Boulton, Wright and MoseleyBoulton, [^c 1975]); and secondly, the relatively smaller cohesive strength of ice-cemented sand compared to most rock masses. The existence of ice strata, zones of low ice saturation of intergranular voids, and large open voids will all tend to facilitate this process. I suggest that the large voids reflect major differential movement of adjacent joint-bounded masses.

The problem of incorporating masses of subglacial material into a glacier and transporting them more than a few centimetres above the glacier bed was recognized by Reference WeertmanWeertman (1961) when he proposed that net freezing-on of subglacial melt water to the glacier sole in the outer cold zone of a sub-polar glacier could produce thick englacial debris sequences. However, this will not suffice at the snout of Wright Lower Glacier as there is no free water. The temperature at the base of the ice cliff, measured in a 6 m probe, was — 15.4°C.

The difficulty of appealing to shear planes as agents of incorporation is that, for two-dimensional flow, the down-glacier ice must be stationary whilst the sediment layer is incorporated, which would require very strange patterns of movement to incorporate a multi-layered debris sequence. However, this difficulty disappears if we consider flow over a realistic three-dimensional bed. When a glacier flows over a hummock, which is not elongated transverse to flow, the ice moving round the flanks of the hummock often flows into the lee-side position more rapidly than that moving over the summit. Thus, sediment masses torn from the summit or transported over the summit of a hummock may rise above the glacier bed by flow of flanking ice beneath it.

The basal freezing mechanism of Reference WeertmanWeertman (1961) has been widely used and developed (Reference Boulton, Price and SugdenBoulton, 1972; Reference Clayton, Moran and CoatesClayton and Moran, [^c1974]; Reference Sugden, Waters and BrownSugden, 1974), but as yet there is no direct evidence that it occurs. There is no reason to doubt the hypothesis but perhaps we should review the many geological situations in which it has been used as an explanation to inquire if in some cases the process described here could be responsible.

The existence of a frozen substratum of unlithified sediment does not necessarily inhibit large-scale subglacial deformation. If the unlithified substratum is thick and only its upper part is frozen, precisely the same rapid deformation may occur beneath the frozen/unfrozen sediment interface, as occurs immediately beneath the glacier sole at Breiðamerkurjökull.