Field relationships

General observations on the formation and occurrence of debris bands have been collected during our decades of research at Matanuska Glacier. We visited, sampled and described numerous debris bands, and conducted reconnaissance traverses measuring the locations and orientations of as many debris bands as could be visited safely in an area. Limited radar profiling and drilling have allowed further characterization of the debris bands.

Isotopic composition

Samples of debris-band ice and surrounding ice were analyzed for ³H (t _1/2 = 12.26 years; Reference Gat, Fritz and FontesGat, 1980), δ ¹⁸O and δD. In August 1996, four different laminated debris bands located within the overdeepened basin near the ice margin were sampled, together with clean, bubble-free englacial ice adjacent to those debris bands. Another of the debris bands split in two near the top of an ice ridge, and samples were collected from both limbs, as well as from the clean, bubbly englacial ice between (Fig. 2). Bulk samples were completely melted, with 30 mL of meltwater collected for δ ¹⁸O and δD analysis, and 250 mL collected for enriched ³H analysis. During October 1997, higher-resolution sampling (2 cm resolution for stable isotopes, 6 cm for enriched ³H) was conducted in a similar way across one debris band.

Fig. 2.

Laminated debris band as it appears during the summer months. Debris band splits near the center of the photograph. ³H concentrations at each sample location are: (a) 0.5 TU, (b) 5.4 TU, (c) 0.5 TU, (d) 7.9 TU, (e) 0.3 TU. Only the laminated debris-band ice samples are enriched with the ³H relative to englacial ice. The width of the debris band near the bottom center of the photograph is exaggerated by sediment flowage.

Electrolytic enrichment and scintillation counting techniques (Kessler, 1988) were used to analyze samples for ³H content at the low-level ³H laboratory at Michigan State University. The analytical detection limit is 1 TU (tritium unit) with a precision of ±1 TU. Coastal Scientific Laboratories (Austin, TX) conducted preliminary stable-isotopic analyses with reported precision of ±0.3‰ for δ ¹⁸O and ±5.0‰ for δD. Mountain Mass Spectrometry (Evergreen, CO) analyzed high-resolution δ ¹⁸O and δD samples with reported precision of ±0.02‰ and ±0.20‰, respectively.

Sediment grain-size

Grain-size analyses were carried out on the sediments in the dirty ice of the debris bands following the methods of Reference FolkFolk (1974). Samples were split to approximately 40–50 g, then wet-sieved through a 4ϕ (62 μm) screen. The dispersion step was skipped, because previous detailed studies at Matanuska Glacier have shown the clay content to be <3% (Reference LawsonLawson, 1979). Sand (−1ϕ to 4ϕ) and gravel (−4ϕ to −1ϕ sizes were dried and sieved at 1ϕ intervals (−2.75ϕ and −3.75ϕ were substituted for −3.0ϕ and −4.0ϕ because of missing sieve sizes). Silt content was determined by pipette analysis. Grain-sizes were compared with those of different ice and water types at Matanuska Glacier described by Reference LawsonLawson (1979), and with those likely to be produced by different proposed mechanisms of debris-band formation (Table 1). To test for upward fining, samples were collected along one debris band at different heights above the bed.

Ice fabric

Thin sections of dirty laminated debris-band ice and surrounding englacial ice were made under the tutelage of A. J. Gow (personal communication, 1998) and examined for c-axis fabrics according to the methods of Reference LangwayLangway (1958). Thin-sectioning the debris-rich ice caused local heating and possible melt–refreeze in a few instances, as identified by A. J. Gow (personal communication, 1998). This conclusion was based on the appearance of the sections in normal light during sectioning and on appearance of acicular ice crystals radiating from silt grains in a few regions of thin sections when observed in cross-polarized light. We avoided those limited regions in our analyses. Accuracy of orientation measurement was determined by multiple analyses on samples according to the methods of Reference KambKamb (1961). Trend accuracy was ±7°, and the plunge accuracy was ±5°.

Field relationships

Matanuska Glacier almost certainly includes debris bands formed by different processes. Bands of till form in ice-marginal mélanges during winter, associated with folding/thrusting processes. Farther up-glacier, rare bands of pebble-sized, well-sorted schist chips are observed, likely related to surficial meltwater activity up-glacier.

However, the most characteristic class of Matanuska Glacier debris bands is different from these cases and forms a single, easily recognizable population; further discussion here focuses only on this distinct population. The common debris bands of Matanuska Glacier are laminated, sediment-rich structures observed at the surface within and down-glacier of overdeepened basins near the ice margin (Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998; Reference Evenson, Mickelson and AttigEvenson and others, 1999). These basins are associated with high water pressures due to adverse bed slopes that supercool rising basal waters (Reference Alley, Lawson, Evenson, Strasser and LarsonAlley and others, 1998).

Debris bands are visible only in the ablation zone and only within a few kilometers of the terminal ice margin. The absence of debris bands at the surface further up-glacier in the ablation zone suggests either the conditions for their formation may not be present up-glacier, or that favorable conditions exist but the bands do not penetrate to the ice surface. Limited ground-penetrating radar records from an up- glacier location, which lacks debris-bands at the surface, reveal a few linear diffractors below the surface (D. E. Lawson, unpublished data). The diffractors are interpreted to represent debris bands that fail to reach the glacier’s surface. However, our observations focus on debris bands that are exposed or are forming near the present ice margin.

The visible debris bands typically extend laterally for hundreds of meters (Fig. 1). Some strike generally north-south approximately perpendicular to ice flow, others east-west or in other orientations. Visible debris bands commonly are vertical or dip steeply up-glacier, although down-glacier and even nearly horizontal dips are observed. Dip measurements were made where debris bands were cross-cut by crevasses. Some debris bands split (Fig. 2), or split and rejoin to isolate “lozenges” of englacial ice. Some debris bands can be traced downward into the stratified basal ice (Reference LawsonLawson, 1979; cf. Reference Hubbard and SharpHubbard and Sharp, 1995), but none have been observed to terminate downward above the basal ice. In at least one case, the basal ice has been offset a few centimeters at its contact with a debris band (Fig. 3), but larger offsets have not been observed.

Fig. 3.

Debris band as seen inside anice cave, looking in the down-glacier direction. Film box (bottom) for scale. Arrow A points to the central seam of sediment, which continues in the third dimension, angling off toward the left side of the photograph. Arrow B points to the clear, coarse-grained ice adjacent to the debris band. Arrow C points to the offset of the top layer of the stratified basal ice. Sense of motion would be a reverse thrust. Arrow D points to a continuous layer within the stratified basal ice, indicating debris-band formation took place after the top layer was accreted, but before this layer was accreted.

The sediment in Matanuska Glacier debris bands is visibly concentrated in a centrally located seam (Figs 3 and 4a) or in several subparallel laminae (Fig. 4b). Commonly, the sediment-rich zones occur between subparallel clear, clean ice layers a few centimeters thick that are in contact with and cross-cut stratigraphic or other features in the bubbly, generally clean englacial ice (Fig. 4). Estimated sediment content within debris-rich laminae is approximately 20–50% by weight. However, that value varies widely, as nearly ice-free debris has been observed in at least one debris band. Sediment released from the debris laminae by ablation forms sediment flows on the ice surface (e.g. Reference LawsonLawson, 1982). The sediment flows in turn cause the debris bands to appear much wider than they really are (Fig. 1). Also characteristic of these debris bands are irregular zones of mostly clear ice with low bubble concentrations that may extend from the clean debris-band layers a few centimeters into surrounding englacial ice.

Fig. 4.

Layered structure of debris bands, (a) Centrally located seam of sediment is surrounded on either side by clear, coarse-grained ice that is adjacent to coarse-grained bubbly englacial ice. The contact between the clear and bubbly ice is diffuse. (b) Hand sample chipped away from a debris band having multiple laminations. Gloved hand for scale. The ice between sediment laminae is typically very clear (bottom), though the sediment is not always restricted to the laminations (top). Sediment grain-size consists of fine sand and silt.

Open orifices or conduits commonly occur along debris bands (Fig. 5), although most of a debris band’s length along the glacier surface lacks conduits. Conduit diameters range from a few centimeters to a few tens of centimeters. Several conduits typically occur in proximity to one another along a debris band. Conduits characteristically are lined by annuli of platy ice crystals. The conduits resemble Holmlund’s (1988) “fossil moulin” and Reference StenborgStenborg’s (1968) “crystal quirke”. Away from the immediate vicinity of conduits, crystals in debris-band ice typically are elongated normal to the band, consistent with inward growth from the sides. A debris band has also been observed in contact with a large (∼1 m diameter) englacial conduit. Debris extended into the conduit from the band.

Fig. 5.

Two open conduits found adjacent to one another in a debris band. The conduit near the top of the photograph is 10 cm in diameter. Both conduits were open to a depth of approximately 2 m from the ice surface, at which point they appeared to be closed. The conduits may indicate crevasse closure or flow of supercooled water into fractures, with eventual closure by ice growth and ice flow.

Discharge of turbid waters onto the surface of the glacier through debris-band conduits is often observed, typically within 200 m or so of the glacier terminus where ice thicknesses are <100 m. For example, in one instance a series of small (few cm diameter) orifices arrayed in a line a few meters long and transverse to ice flow discharged onto the surface through ice approximately 30 m thick. In another instance, a similar discharge through ice approximately 10–15 m thick occurred along a line roughly 30 m long and parallel to ice flow. One exceptional discharge of turbid water during peak summertime water flow from the glacier occurred into a supraglacial lake at the foot of an icefall about 500 m from the terminus, where the ice was about 100 m thick. Such turbid discharges onto the glacier surface typically occur in summer; however, clear discharges have been observed less frequently in winter following extensive aufeis growth in the proglacial region, which would have tended to block free drainage of ground-water.

In some cases, we have observed opening of basally connected crevasses and discharge of turbid waters leading to debris-band formation. During periods of high subglacial water pressures, as inferred from ice-velocity and water-discharge data and discharges of turbid waters onto the ice surface (Reference Ensminger, Evenson, Alley, Larson, Lawson, Strasser, Mickelson and AttigEnsminger and others, 1999a), fieldworkers in and near the ice-marginal overdeepened basin have heard and felt long-lasting (seconds or more), ringing (non-impulsive) “ice quakes’’, which suggest crevassing of the glacier (Reference Blankenship, Anandakrishnan, Kempf and BentleyBlankenship and others, 1987). New crevasses opened during such periods, and some but not all of these crevasses connected with the basal water system as evidenced by the upwelling of silt-laden waters and growth of silt-laden frazil ice (Fig. 6). These basally connected crevasses typically reach the surface only where the ice is thinnest and the surface lowest, continuing laterally but failing to reach the surface in thicker ice (Fig. 6). Newly formed crevasses often cross-cut older ones, suggesting multiple generations of formation under changing stress states (e.g.Reference Whillans, Bentley, van der Veen, Alley and BindschadlerWhillans and others, 2001).

Fig. 6.

Crevasses connecting to the basal drainage system upwell with debris-rich water, (a) Basal crevasse exposed at the surface along a 10 m segment of its length. Crevasse is “blind” inupper part of the photograph. (b) Ice growth inward from the walls of the crevasse exposed during the diurnal low-flow period. Mountaineering axe-head 30 cm for scale.

Tritium concentrations

The four laminated debris bands sampled during 1996 are significantly enriched in ³H compared with englacial ice (7.0 TU vs <1 TU, different with >98% confidence based on t tests; Table 2). Isotopic fractionation during freezing is small compared with these differences and can be ignored (Reference Strasser, Lawson, Larson, Evenson and AlleyStrasser and others, 1996). The high ³H concentrations indicate presence of bomb-produced ³H, similar to post-1952 precipitation. Debris-band ³H concentrations are similar to those of basal meltwater, and ice grown from that meltwater, but distinct from the englacial ice of which most of the glacier is composed (Table 2; see also Reference Strasser, Lawson, Larson, Evenson and AlleyStrasser and others, 1996). However, the laminated debris band sampled in detail during 1997 had ³H concentrations not much higher than those of englacial ice (1–3 TU vs ∼1 TU for englacial ice; Fig. 7). Formation of this band probably occurred before 1952, and probably >3 km up-glacier based on extrapolation of measured ice velocities near the margin (Reference Ensminger, Evenson, Alley, Larson, Lawson, Strasser, Mickelson and AttigEnsminger and others, 1999a; cf. Reference Titus, Larson, Strasser, Lawson, Evenson, Alley, Mickelson and AttigTitus and others, 1999).

Table 2.

Maximum, minimum, and ³H values (TU) of dirty ice from bulk debris-band samples and their surrounding englacial ice compared with different ice and water types at Matanuska Glacier

Fig 7

Isotopic values of a transect across a laminated debris band (0–18 cm), clear englacial ice (18–27 cm) and bubbly englacial ice (27–30 cm). A thin section of the debris-band ice is shown above in normal light. Note that the clean ice in the debris band (8–12 cm) has lighter stable-isotopic values than the debris-rich debris-band ice (4–6 and 12–18 cm). ³H values are not significantly above background levels.

Stable-isotopic ratios

Stable-isotopic data are listed in Table 3. Previous work at Matanuska Glacier (Reference Lawson and KullaLawson and Kulla, 1978; Reference Strasser, Lawson, Larson, Evenson and AlleyStrasser and others, 1996; Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998; Reference Titus, Larson, Strasser, Lawson, Evenson, Alley, Mickelson and AttigTitus and others, 1999) has shown that much of the subglacial discharge is derived from melting of englacial ice with little isotopic fractionation. Frazil, anchor and stratified basal ice grow in front of and beneath the glacier by freezing a very small fraction of the voluminous subglacial discharge during supercooling conditions in an open hydrologic system (Reference Titus, Larson, Strasser, Lawson, Evenson, Alley, Mickelson and AttigTitus and others, 1999). Taken together, frazil, anchor and stratified basal ice are isotopically heavier than the ice in dirty laminae of debris bands with >99% confidence based on a t test of their oxygen- and deuterium-isotopic ratios. The ice in dirty laminae is heavier than the ice in clear laminae and irregular regions of clear, bubble-free ice adjacent to the debris bands, which in turn are slightly heavier than englacial ice. The difference between isotopic ratios of ice in the dirty laminae and the englacial ice is significant with >95% confidence based on a t test.

Table 3.

Maximum, minimum, and average δ¹⁸O and δD values (per mil) for dirty laminated debris-band ice, clear laminated debris- band ice and their surrounding englacial ice compared with different ice and water types at Matanuska Glacier

Sediment grain-size

Sediment found within the debris-band ice had an average grain-size of 4.8ϕ (coarse silt) and was fairly well sorted (s = 2.7ϕ; Fig. 8). This closely resembles the suspended load in the subglacial streams discharging from Matanuska Glacier (Reference LawsonLawson, 1993), and is not statistically distinguishable from the fine-fraction of the stratified basal ice. The grain- size distribution of the sediment in the debris-band ice does not resemble the angular supraglacial debris described by Reference LawsonLawson (1979) (−3ϕ to 1ϕ), and resembles only the fine fraction of debris in subglacial sediments (sand to silt; Reference LawsonLawson, 1979). The debris bands entirely lack a coarse fraction and striated stones observed in subglacial and proglacial streams and tills.

Fig. 8.

Sediment grain-size distributions for vent frazil ice, stratified basal ice and debris-band ice. The sediment in debris-band ice is extremely well-sorted fine sand. Grain-size distribution in basal- and frazil-ice types is not unimodal and contains greater volume percentages of coarse sand and pebbles.

Ice fabric

Figure 9 shows the orientation fabrics of the englacial ice on either side of a low-³H debris band and of the debris-free ice in the debris band. Insufficient orientation data were obtained from debris-rich ice for statistical analysis, due to melting and refreezing during the thin-sectioning process. There is little difference between texture and fabric of the debris band and surrounding englacial ice.

Fig. 9.

c-axis orientations from horizontal thin sections of (a) 25 englacial ice crystals from one sample, and (b) 21 clear debris-band ice crystals from one sample. In thefield, samples were not oriented at the time of collection. Therefore, the Schmidt equal-area lower-hemisphere stereographic plots can be freely rotated. A total of 91 orientations were measured in the englacial ice, and 75 were measured in clear debris-band ice taken from multiple samples. Both ice types show four weak fabric maxima. Accuracy of measurements was ±7° for the trend and ±5° for the plunge.

Debris-band origin

As noted above, debris bands are undoubtedly polygenetic across glaciers and even at Matanuska Glacier. However, our data provide high confidence that the common debris bands of Matanuska Glacier were formed by injection of turbid waters into basal crevasses.

The Matanuska Glacier debris bands lack coarse clasts related to shearing or folding of basal debris into the ice, or squeezing/creep of till into large basal crevasses. Instead, the size distribution of the debris is similar to that of the suspended load of subglacial discharge and of ice grown from supercooling of that subglacial discharge.

The debris-band ice is isotopically distinct from adjacent englacial ice, whereas materials buried supraglacially or sheared or folded in would probably occur in englacial ice. The debris-band ice does show isotopic similarities to ice grown from proglacial and subglacial waters. ³H concentrations are elevated in most debris-band ice tested. Such levels are distinct from englacial ice but are instead similar to subglacial waters and to ice known to have grown from those subglacial waters. Stable-isotopic ratios of the debris- band ice differ significantly from those of englacial ice and basal meltwaters, but are consistent with origin by freezing from basal meltwaters, as discussed below. Additionally, the lack of air bubbles in debris-band ice would suggest a possible accretionary origin for it (Reference Gow, Epstein and SheehyGow and others, 1979).

Limited data from one debris band show c-axis fabrics similar to those in adjacent englacial ice. Anomalous c-axis fabrics associated with strong localized shearing or folding (e.g. Reference Gow and WilliamsonGow and Williamson, 1976; Reference Budd and JackaBudd and jacka, 1989; Reference AlleyAlley, 1992; Reference PatersonPaterson, 1994) are absent. However, this debris band proved to have low ³H levels, suggesting that it may have formed before 1952 well up-glacier, so we cannot exclude the possibility that a fabric associated with localized shearing has been removed by subsequent recrystallization under “normal’’ glacier flow to cumulative strains of order 10% or more (Reference Budd and JackaBudd and jacka, 1989).

Finally, field observations show debris-band formation through ice growth on new crevasse walls into upwelling turbid-water discharges reaching the glacier surface. With this weight of evidence, we argue that the common Matanuska Glacier debris bands were formed by injection of turbid basal meltwater into basal crevasses.

Active processes

Although the broad outline of the formation mechanism of Matanuska Glacier debris bands thus is clear, many of the details are not. However, available data provide some insight and suggest further hypotheses.

Field observations show that turbid basal meltwaters are injected into narrow cracks or fractures, which we call basal crevasses although there is no evidence that they typically open wider than millimeters. These basal crevasses reach the upper ice surface in some places, but probably more typically terminate upwards below the surface. Upward water flow occurs both in widespread sheets and occasionally through concentrated vents, producing ice-crystal growth into the spaces.

Thermodynamic considerations (Reference Alley, Lawson, Evenson, Strasser and LarsonAlley and others, 1998) as well as field observations indicate that the rise in the pressure-melting temperature in response to falling pressure on upwel- ling water can cause supercooling and ice growth. Thus, ice growth is expected during water injection and throughflow.

In addition, earlier work on temperate glaciers suggests that some in situ freezing may occur in waters trapped in crevasses following injection. Reference HarrisonHarrison (1972) noted that boreholes in temperate glaciers typically close by freezing, and discussed contributions to this freezing from the effects of impurities, dissolved gases and stress state. Reference RaymondRaymond (1976) further noted that stresses associated with overpressured bubbles in ice flowing towards the surface in the ablation zone will lower the melting point in that ice.

We thus expect that many processes contribute to debris- band formation. Water injected into a basal crevasse may escape upward to the surface, laterally into englacial drainage channels, or back downward in response to a subsequent fall in basal water pressure, with small amounts “soaking” adjacent ice by moving into bubbles or intergranular veins along the crevasse, and with some diffusive exchange with adjacent englacial ice. Sediment may be trapped between growing crystals, in adjacent veins or bubbles, or by asperities on the fracture surfaces. Ice may grow from supercooling of upwelling waters owing to falling pressure, or from stress reliefassociated with crevassing or other processes affecting nearly stagnant waters trapped in fractures following injection.

Our isotopic and sediment-grain-size data suggest that several of these processes have been active in formation of the observed debris bands of Matanuska Glacier. The debris bands commonly have high (>2 TU) ³H concentrations, indicating freezing of waters that fell as precipitation more recently than the first large atmospheric atomic-bomb tests in 1952. The ³H content of the debris bands is close to or slightly lower than expected for recent freezing of summertime basal meltwaters (2.5–8 TU, Reference Strasser, Lawson, Larson, Evenson and AlleyStrasser and others, 1996; Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998; Reference Titus, Larson, Strasser, Lawson, Evenson, Alley, Mickelson and AttigTitus and others, 1999), which is consistent with recent formation and with only a little diffusive or other admixture of H-free englacial ice.

The ³H data also could be explained by debris-band formation soon after atmospheric atomic-bomb testing, when ³H concentrations were higher, or more recently during wintertime from the relatively ³H-enriched ground-water (26 TU; Reference Strasser, Lawson, Larson, Evenson and AlleyStrasser and others, 1996; Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998), and large dilution by diffusive or other admixture of ³H-free englacial ice. However, these models are inconsistent with our observations that basal crevassing usually is a summertime phenomenon and occurs primarily near the glacier terminus.

The ³H data thus suggest that the dirty ice of debris bands is primarily refrozen meltwater rather than englacial ice. The stable-isotopic data then suggest that this dirty ice grew both from an open hydrological system and by in situ closed-system freezing. The stable-isotopic ratios of the dirty laminae of debris bands typically are lighter than frazil, anchor and stratified basal ice types that have grown by freezing of only a small fraction of through-flowing water in an open hydrological system (Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998), but are heavier than englacial ice, basal meltwater and any ice that would form by complete refreezing of basal meltwater (Reference Souchez and LorrainSouchez and Lorrain, 1991; Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998). This is most easily explained if both open- and closed-system ice are present in the debris bands.

The sediment grain-size variation with height above the bed also bears on this issue. Where samples were collected along one debris band, the average sediment grain-size at an unknown height above the bed was 4.78ϕ (n =15), and the average grain-size in that same debris band about 10 m higher was 5.58ϕ (n = 5), indicating upward fining with about 75% confidence based on a t test. Stokes’-law settling velocities for clasts of this size are on the order of 1 mm s⁻¹. Slight upward fining on this scale is consistent with upward fluid-flow velocities slightly higher than the settling velocity but of the same order of magnitude. Faster flows would have swept the sediment out of the system before significant sorting had taken place. Water emerging from conduits at the surface typically flows much faster than this, indicating that the debris band was not formed primarily from such conduit flow. However, water standing freely in a crevasse for a few days or longer would have allowed greater sorting than observed. Accepting the measured upward fining at face value permits slow opening of basal crevasses, slow sheet-like throughflow of water, or more rapid opening and injection followed by closing in some fashion over the order of 1 day.

Taken together, these observations indicate that multiple processes contribute to debris-band formation, including open-system freezing from upwelling waters and in situ freezing from injected waters. This interpretation, while not unique, is in good accord with field observations.

Several additional hypotheses require testing with further data. The complex layered structure of many debris bands suggests multiple crevasse-opening events, with later crevassing exploiting planes of weakness left by imperfect crevasse closure from previous events. Such exploitation of a pre-existing debris band occurred along one band during the summer 2000 field season. We cannot rule out the possibility that some of the clear laminae within debris bands represent a plastic process zone formed during fracturing (Reference Engelder, Fischer and GrossEngelder and others, 1993), rather than an origin by soaking or by the injection of clean water in some other way. Debris bands may be subject to post-freezing modification, such as slight melting if weathering of silt produces ions that lower the melting point of dirty ice after stress equilibration, although the recent formation of most bands argues against large changes in this way (Reference EnsmingerEnsminger, 2000). Finally, conduits that localize upwelling water flow along some crevasses may be former moulins, which may be important in nucleation or propagation of the basal crevasses.

Occurrence of basal crevassing

Basal crevassing is increasingly understood to be a widespread phenomenon, having been observed in many glacial environments or inferred on the basis of good evidence. These environments include floating ice shelves (e.g. Reference Jezek, Alley and ThomasJezek and others, 1985), an Antarctic ice stream (Reference Novick, Bentley and LordNovick and others, 1992), tidewater calving termini (e.g. Reference Mickelson and BerksonMickelson and Berkson, 1974), surging glaciers (e.g. Reference SharpSharp, 1984) and an outlet glacier during a jökulhlaup (Reference Roberts, Russell, Tweed and KnudsenRoberts and others, 2000).

Basal crevassing is favored by high basal water pressures to offset the weight of the ice, by longitudinally extensional stresses in basal ice and by heterogeneities that serve to nucleate fractures, all of which are features of Matanuska Glacier. Ice flow over rough topography, as evidenced by ground-penetrating radar beneath Matanuska Glacier (Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998), is expected to produce regions that are locally extensional as well as locally compressive. For example, Reference HansonHanson (1995, and personal communication, 2000) modeled flow of Storglaciären, Sweden, and found basal values of extensional longitudinal-deviatoric stresses of >120 kPa in ice flowing into the upper overdeepened basin, and >40 kPa flowing into the lower overdeepened basin. Matanuska Glacier, with faster flow (Reference Ensminger, Evenson, Alley, Larson, Lawson, Strasser, Mickelson and AttigEnsminger and others, 1999a) and rougher basal topography (Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998), is likely to generate similar or larger stresses. Fountains of turbid basal water occasionally released onto the surface of Matanuska Glacier document the occurrence of high basal water pressures locally in excess of flotation. Observations of the basal zone show that the basal ice is heterogeneous (Reference Lawson, Strasser, Evenson, Alley, Larson and ArconeLawson and others, 1998), providing contrasts that along with moulins could serve to nucleate fractures. Matanuska Glacier is thus a likely candidate for basal crevassing.

Field observations indicate that crevassing usually occurs without significant thrusting or strike-slip motion, so that crevasses are primarily mode-I or opening-mode cracks (Reference PatersonPaterson, 1994), with the greatest extensional stress parallel to the bed and most typically in the direction of ice flow through the overdeepened basin. However, the few- centimeter offset of basal ice along the debris band shown in Figure 3 indicates that mixed-mode fractures can also occur (cf. Reference Hambrey and MüllerHambrey and Muller, 1978). The splitting and rejoining of some debris bands around lozenge-shaped regions of englacial ice may also indicate some component of shear in that part of the debris band (Reference SchulsonSchulson, 1987).

Abrupt water-pressure changes associated with crevassing may be important in driving fractures through subglacial rock, and thus in facilitating erosion (Reference IversonIverson, 1991). The longitudinal extension associated with flow into overdeepened basins (Reference HansonHanson, 1995) would tend to localize basal crevassing, and any associated water-pressure variation and erosion, on the headwalls of overdeepened basins (Reference Alley, Strasser, Lawson, Evenson, Larson, Mickelson and AttigAlley and others, 1999). The effects would contribute to the feedbacks identified by Reference HookeHooke (1991) that serve to generate and strengthen overdeepened basins (Reference Alley, Strasser, Lawson, Evenson, Larson, Mickelson and AttigAlley and others, 1999). Basal crevassing also may provide a mechanism by which basal and englacial waters can mix (cf. Reference Humphrey, Kamb, Fahnestock and EngelhardtHumphrey and others, 1993; Reference Hooke and PohjolaHooke and Pohjola, 1994) and be forced into the englacial zone (Reference WeertmanWeertman, 1973; Reference HolmlundHolmlund, 1988; Reference Lawson and HunterLawson and Hunter, 1996).