Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-12-05T02:26:03.397Z Has data issue: false hasContentIssue false

Glacial land forms indicative of a partly frozen bed

Published online by Cambridge University Press:  20 January 2017

Johan Kleman
Affiliation:
Department of Physical Geography, Stockholm University, S-106 91 Stockholm, Sweden
Ingmar Borgström
Affiliation:
Department of Physical Geography, Stockholm University, S-106 91 Stockholm, Sweden
Rights & Permissions [Opens in a new window]

Abstract

In parts of the core area of the Fennoscandian ice sheet relict periglacial surfaces occur. The boundary between periglacial and glacial landscapes is often sharp and erosional, with fluting truncating patterned ground. The periglacial surfaces are older than the last ice sheet and are interpreted to represent patches of continuous frozen-bed conditions. A specific land-form assemblage occurs at the edges of such patches. On the basis of three type localities along the eastern rim of the Scandinavian mountains, four thermal boundary land forms, characteristic of the frozen-patch environment, are defined. Stoss-side moraines and transverse till scarps, not previously described, are interpreted to have formed in detachment zones where soil frozen to the glacier overlies thawed soil. The detachment zones are located where subglacial warming raises the phase-change surface (water/ice) until it intersects the soil layer up-and down-glacier from residual frozen-bed patches. The up-glacier ends of frozen-bed patches are located on topographic highs, but down-glacier the location of lateral sliding boundaries is occasionally independent of topography. The identification of relict surfaces and thermal boundary forms can improve paleo-ice-sheet models by providing estimates of the extent of frozen-bed conditions.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1994

Introduction

In the following we describe an assemblage of subglacial land forms that we interpret to have formed at the edges of frozen-bed patches. These patches provide information about the distribution of frozen-bed and thawed-bed areas beneath parts of the last Fennoscandian ice sheet. Ice-sheet models usually depict broad thermal zones, either arranged concentrically (Reference SugdenSugden, 1978; Reference Denton and HughesDenton and Hughes, 1981) or topographically, or substratum controlled (Reference Fastook and HolmlundFastook and Holmlund, 1994). One of the striking features of glacial morphology maps (Reference Prest, Grant and RamptonPrest and others, 1968; Reference Sollid and KristiansenSollid and Kristiansen, 1982; Reference Borgström,Borgström, 1989) is, however, the “patchiness” of the glacial bed-form distribution in former core areas of ice sheets. Fields of distinctly different bed forms often occur in radially arranged fans, suggesting important differences, trans-verse to flow lines, in the subglacial environment.

Observational or geological evidence for basal thermal patterns has been available principally at the “very small” and “very large” ends of the continuum of spatial scales. Freezing-thawing patterns at the size of individual roches moutonnées have been observed (Reference CarolCarol, 1947; Reference Goodman, King, Millar and RobinGoodman and others, 1979) and evidence also exists for basal thermal patterns on the scale of large palco-ice streams (10-200 km) (Reference Dyke and MorrisDyke and Morris, 1988). However, few instances of intermediate-scale basal thermal patterns in the low-to medium-relief terrain that areally dominated the Scandinavian and Laurentide ice sheets have been described.

Here we deal with a special subglacial land-form assemblage occurring on the 1-10 km scale. These patches occur on low uplands with a completely preserved periglacial landscape of pre-late Weichselian age, surrounded by late Weichselian fluting. Locations are shown in Figure 1. The boundary between the periglacial and glacial landscapes is often sharp and erosional, as where fluting truncates patterned ground (Figs 2 and 3), and can only be explained as the result of glacial erosion after the formation of the periglacial landscape (Reference Kleman and BorgströmKleman and Borgström, 1990). We therefore have remnants of a ground surface that have survived fully intact beneath an ice sheet. In all probability, the survival of these relict surfaces results from uninterrupted frozen-bed conditions (Reference LagerbäckLagerbäck, 1988b; Reference Kleman and BorgströmKleman and Borgström, 1990; Reference Kleman, Borgström, Robertsson and LilliesköldKleman, 1992). Field evidence for preservation of landscapes and land forms under cold-based parts of ice sheets has also been reported from the Laurentide area (Reference Sugden and WattsSugden and Watts, 1977; Reference Dyke and MorrisDyke, 1983; Reference Dyke, Morris, Green and EnglandDyke and others, 1992). In the following the term “relict surface” is used for a surface that was ice-covered but not modified, regardless of whether it is a subaerially formed surface or a glacially sculpted surface from an older flow phase. Hence, relict surfaces are taken to represent former frozen-bed areas.

Fig. 1. Location map. Numbers show location of sites mentioned in text. 1, Tjuolma; 2, Arvestuottar; 3, Långfället; 4, Städjan; 5, Häggingßället; 6, Fulufjället; 7, Transtrand.

Fig. 2. Map of the Arvestuottar area. The relict surfaces (A, B), marking the sites of former frozen-bed patches, are located on topographic highs and are elongated in the ice-flow direction. Boxes show locations of Figures 3 and 4. Moraine ridges (D,E) occur proximally and laterally to the relict surfaces.

Fig. 3. Vertical aerial photograph of a lateral sliding boundary (C) at Arvestuottar. The area to the left of the boundary bears patterned ground and lacks glacial flow features. It is interpreted as a relict (interstadial) surface, preserved by continuous frozen-bed conditions. The area to the right is fluted and lacks patterned ground.

The last glaciation in central Scandinavia was during the late Weichselian. The minimum duration of the last ice cover was around 20 ka but the actual length was more probably 50 ka (Reference Andersen and MangerudAndersen and Mangerud, 1989). The glacial history of west-central Sweden has been discussed by Reference Borgström,Borgström (1989), Reference Kleman and BorgströmKleman and Borgström (1990), Reference KlemanKleman (1990) and Reference Kleman, Borgström, Robertsson and LilliesköldKleman and others (1992).Accounts of the glacial history of northern Sweden have been given by Reference LagerbäckLagerbäck (1988a, Reference Lagerbäckb), Reference Lagerbäck and RobertssonLagerbäck and Robertsson (1988) and Reference Kleman, Borgström, Robertsson and LilliesköldKleman (1992). In both areas, land forms from late stages of the last stadial are overprinted on abundant (northern Sweden) or scattered (west-central Sweden) land forms from previous ice sheets. At the three localities we have studied, the last deglaciation occurred during the time interval 10000—9000 BP; deglaciation was continuous and rapid, without any signs of halts or re-advances (Reference KlemanKleman, 1990, Reference Kleman, Borgström, Robertsson and Lilliesköld1992; Reference Lundqvist and KauranneLundqvist, 1992).

Localities

The most clearly delineated frozen-bed “patches” yet located in Sweden are at Avestuottar, Häggingfjället and Fulufjället. All three are located on undulating uplands at 800-1000 m a.s.l. In the following paragraphs we will describe the salient features of each locality.

Arvestuottar

Patch A in Figure 2 is a striking patterned-ground area devoid of any glacial land forms. It is aligned with the last recorded ice-flow direction. The lateral borders of the patch (C in Figures 2 and 3) are sharp and hence erosional. At C, the full change from a patterned-ground surface to a fluted surface occurs within less than 20 m. The northeastern boundary of patch A first rises in the direction of flow, then decreases in elevation, and then rises again, resulting in what we call an up-down-up profile. Trim lines around nunataks should be expected to descend monotonously in the down-glacier direction and we therefore consider these profiles to reflect subglacial boundaries. The sharp erosional contacts are interpreted as marking the limit between thawed bed and frozen bed. Similar sharp contacts between fluted till and polygon-ized relict surfaces have also been identified at Langfjället, Städjan, Fulufjället and Tjuolma (Reference Kleman, Borgström, Robertsson and LilliesköldKleman, 1992), and have been referred to as “lateral sliding boundaries” (Reference Dyke and MorrisDyke and Morris, 1988).

The upstream end of patch A rests on Sjuva, a rounded hill. The patch extends as a ribbon down-flow from this summit. The central part of the patch lies on a valley slope. Therefore, although topography exerted broad control in fixing the position of the stoss end of the patch, its sides were determined by the ice-flow pattern, not by breaks in slope, and hence not by changes in ice thickness. Basal sliding has occurred on adjacent higher as well as lower ground.

At some distance from the boundary, the fluting direction conforms with the general fluting direction over the map area. However, along the central part of patch A, the fluting direction close to the margins deviates considerably from the regional fluting direction. If these flutes formed in strict alignment to the flow direction, which is generally to be assumed, then the flow of basal ice leaving the patch was clearly divergent, by about 10°. Where fluting indicates basal flow obliquely out of the patch, a low step separates the higher relict surface from the lower fluted surface. The same relationship has been found at Långfjället.

The distal part of the northeast lateral boundary is formed by a 600 m till ridge (D in Fig. 2 ). This ridge is in a location similar to that of the drumlin-field boundary ridge (lateral shear moraine) described by Reference Dyke and MorrisDyke and Morris (1988). Ridge D is located on a section of the lateral sliding boundary where fluting points slightly into the preserved patch. Thus, there are indications that flow obliquely into the patch led to accumulation of debris while flow obliquely out of the patch was associated with erosion.

At Tuorpun (E, Figs 2 and 4) a transverse moraine ridge occurs directly up-glacier from patch B. Its north-eastern part is multi-crested and is concave down-glacier. Similar stoss-side ridges occur on other hills near the map area. A transverse ridge in a similar location relative to a relict surface is found in the upper left corner of Figure 2.

Fig. 4. Stereogram of the stoss-side ridge (E) at Tourpun, Arvestuottar. The ridge is localedashort distance up-glacier from a relict surface. See Figure 2 for location.

Häggingfjället

Häggingfjället is a gently rounded mountain with two summits (Fig. 5 ). Local relief (within 5 km) is about 400 m, whereas regional relief is about 600 m. Although the two summits (A and B in Figures 5 and 6) are only 1 km apart, they differ completely in the morphology of their soil cover. The higher western summit (B) is entirely fluted, has several fields of large glacially transported boulders (boulder blanket; see Reference Kleman and BorgströmKleman and Borgström, 1990) drawn out along-flow and lacks patterned ground. The eastern summit is partly fluted but also has a large area (C, Figs 5 and 6) characterized by stone stripes and sorted polygons. The margins of this periglacial area are erosional, but the sides and proximal edge are not as sharp as at Arvestuottar and Fulufjället; the transition from polygonized surface to fluted till occurs over a distance of about 100 m.

Fig. 5. Map of the Häggingfjället area.

Fig. 6. Vertical aerial photograph of the eastern summit of Häggingfjället. The relict surface (C) is truncated by a cross-mountain till scarp.

Periglacial area C ends abruptly down-glacier at a 3-15 m high till scarp that descends to bare bedrock. The bedrock shows a few striations but no developed roche moutonnée shapes. This may be an indication that sustained wet-based ice flow did not occur immediately down-glacier from the scarp. A few hundred metres down-glacier from the bedrock area the ground is completely covered by a 0.5 km2 boulder blanket. As there is no other large bedrock exposure for some kilometres in the up-glacier direction, we infer that the boulders were transported only a short distance. The boulder blanket has tails drawn out in the direction of the fluting. Neither on the sloping till scarp nor on the western summit have any significant sorting phenomena developed since the last glacial event.

Fulufjället

In contrast to Arvestuottar and Häggingfjället, a preserved periglacial landscape dominates the Fulufjället plateau (Figs 7 and 8). Fluting and other evidence of ice flow are restricted to a corridor (A) aligned along-flow and to “holes” (B and E) in the old patterned-ground surface. Deglacial ice flow over the plateau was from the north-northwest. The down-glacier end of patch B comprises a low crescentic boulder ridge (C) with minor crests transverse to ice flow. At the up-glacier end of patch B there is a shallow depression with ridges separating numerous small lake and tarn basins. Such basins are absent in the undisturbed relict surface surrounding patch B. We find it probable that the pre-existing soil cover was extended and fractured in this part of the patch. By visual estimate, the volume of material in ridge C matches the volume of the depression at the up-glacier end of the patch. It therefore appears that no material was added to or removed from the patch during the late Weichselian stadial. Patch B may represent only short-lived warm-based conditions.

Fig. 7. Map of the relict surfaces and sliding-bed zones (A, B, E) at Fulufjället. The down-glacier end of the fully enclosed sliding patch (B) is marked by an arcluate boulder ridge (C). The arcuate ridge (D) is interpreted to have an origin similar to (C) but has later been subjected to basal sliding and partial destruction.

Fig. 8. Vertical aerial photograph of the Tangåfjället and R. Tangån sliding zones, Fulufjället. See Figure 7 for interpretation.

The River Tangån fluted-till corridor (Fig. 7 ) follows a shallow valley characterized by glacially transported boulder blankets and fluting, but lacking the periglacial features that are present immediately to the east and west (Fig. 9 ). The corridor is displaced from the valley axis such that the western side follows the valley bottom but the eastern side is much higher. As at Arvestuottar, the flutings show slight convergence towards the sliding zone. The arcuate till and boulder ridge at Tangsjöarna (D, Fig. 7 ) may be a modified stoss-side moraine, as at Arvestuottar (E, Fig. 3 ), that was later over-run and partly destroyed when the sliding patches expanded in size.

Fig. 9. Relict surfaces at Fulufjället. These surfaces are characterized by boulder depressions and large sorted polygons. Such features are lacking in adjacent areas showing evidence of basal sliding.

The “Frozen Patch” Land-Form Assemblage

The relict surfaces described here are windows in which periglacial features are preserved, framed by larger expanses of glacial erosion. Somewhat similar windows described elsewhere may reveal old glacial landscapes surrounded by younger landscapes with differently oriented flow lineaments (Reference Dyke and MorrisDyke and Morris, 1988; Reference Lagerbäck and RobertssonLagerbäck and Robcrtsson, 1988).

In the eastern part of the Scandinavian mountain range, such relict surfaces are characterized by one or more of the following features: large sorted polygons, stable felsenmeers, ventifacts, deeply weathered bedrock and tors. Glacial lineations are generally absent but meltwater channels cut through many of the relict surfaces. In some areas, the channels reflect two or more deglaciations (Reference RodheRodhe, 1988; Reference KlemanKleman, 1992). In all probability, these surfaces received their last subaerial imprint during an early Weichselian interstadial (Tärendö interstadial; Reference LagerbäckLagerbäck, 1988a). Theoretically, debris may have been transported englacially across relict surfaces but, except for scattered boulders perched on the otherwise monotonously flat periglacial surfaces, there is little evidence for any significant melt-out during the final deglaciation.

The relict surfaces, including the features characteristic of these surfaces, and the four types of thermal-boundary land forms described from Arvestuottar, Häggingfjället and Fulufjället (Fig. 10, features 2-5) constitute what we call “the frozen-patch land-form assemblage”. We consider these land forms to be important tracers for patchy bed conditions.

Fig. 10. Five land forms characteristic of the frozen-bed patch environment shown on an idealized mountain. The four thermal boundary land forms are shown in the relative positions in which we have repeatedly identified them.

To summarize, the four thermal boundary land forms are:

Lateral sliding boundary. A sharp boundary or a narrow transition, laterally separating a zone of subglacial lineations from a truncated relict surface.

Lateral shear moraine. A ridge parallel or sub-parallel to a flow line between a glacially lineated and a relict surface.

Stoss-side moraine. A transverse single-or multi-crested moraine ridge near the proximal edge of a relict surface.

Transverse lee-side till scarp. A scarp in till, oriented transversely to ice flow, separating a proximal relict surface from a distal scoured or otherwise glacially modified surface.

Note that, although boulder blankets are often found at the edges of relict surfaces, they are not unique to that environment, in contrast to the other forms, and are therefore not included in the “frozen-patch land-form assemblage”.

Thermal Patterns in the Basal Environment

The four boundary land forms described above are found only at the edges of former frozen-bed patches. The origin of these land forms is therefore discussed in the light of the three-dimensional thermal distribution in the basal ice-soil-bedrock environment. Previous work (Reference KlemanKleman, 1990, Reference Kleman1992), and our interpretation of the regional ice-sheet evolution described below, indicates that the frozen patches are remnants of larger continuous frozen-bed zones. That is, basal temperatures were rising but the pressure-melting point was not reached everywhere before deglaciation.

In terms of land-form development in a subglacial shear field, the interactions of three surfaces and one layer are considered important. These are:

  • 1. The ice/soil contact.

  • 2. The soil/bedrock contact.

  • 3. The soil layer.

  • 4. The phase-change (water/ice) surface, here called the PCS. This surface separates thawed regions from overlying frozen regions. It exerts an important control on the strength of subglacial material and thereby subglacial land-form development. The PCS approximates an isotherm but is not strictly so, as the melting temperature depends on pressure and solute content.

Here we use a simplistic, binary, “strength” classification, in which the strength across the ice/soil and the soil/bedrock contacts is considered to be high if the contacts are frozen but low if they are thawed (Reference HughesHughes, 1973). Detachment is expected to occur at the PCS, because it separates strong materials from weak ones. The location of the PCS within the substrata, as well as the flow regime (compressive/extending flow) will determine the type of morphological traces that result. As we move downwards from the ice into the substrata, the following relationships are expected:

If the PCS is located at the ice/soil contact, detachment will occur, resulting in basal sliding. Fluting is the expected morphological expression.

If the PCS is located within the soil or at the soil/bedrock interface, detachment may occur. Detachment at these levels will lead to entrainment and down-glacier movement of debris sheets. The morphological expression will depend on the down-glacier fate of these sheets. If they are deposited, stacked one upon another, then positive, mostly transverse land forms are to be expected. If debris sheets are moved down-glacier, they normally will be stretched, thinned and dispersed.

If the PCS is located in strong bedrock, no detachment is likely to occur. Ice flow is then achieved only by ice deformation and hence this situation leaves no traces.

Origin of Land Forms

Figure 11 shows the PCS intersecting the slopes of a hill. At the summit, the PCS is located well down in strong bedrock. Over topographically lower areas, the PCS is located at the ice/soil contact and basal melting, as well as sliding, occurs.

Fig. 11. This shows how a phase-change surface (PCS), that rises over time, creates two detachment zones where soil frozen to the glacier base overlies thawed soil or the soil/rock interface. The stoss-side ridges are thought to have formed by folding or stacking of debris sheets in front of frozen-bed patches, while the transverse till scarps mark the sites where debris sheets were entrained in an extending flow zone.

The transverse till scarps identified previously (numbering around 15) are all located on the down-glacier sides of hill crests, with relict surfaces or land forms preserved up-glacier from the scarp. Down-glacier from the frozen-bed patch, the PCS passes through the soil cover, creating a zone where soil frozen to the moving glacier sole overlies thawed soil. As strong material is then forced to move on weak material, detachment is likely to occur. Debris sheets are then entrained in a zone of extending flow. The till scarps indicate that the full soil thickness was removed immediately adjacent to places where nothing was removed. We think that event-like entrainment of the full soil thickness (at the scarp) is the most probable process. Thus, the till scarp is likely to mark the intersection between the PCS and the soil/bedrock contact. In the extending-flow zone, dispersal and thinning of the debris sheet will occur, possibly leaving the scarp as the main trace of the debris entrainment. In this context, it can be noted that Reference Hutter and OlunloyoHutter and Olunloyo (1981) pointed out transition lines between frozen and thawed bed as sites of extreme stress concentrations.

Stoss-side ridges are located in the zone up-glacier from the frozen patch, where the PCS also separates an upper layer frozen to the glacier from a lower thawed layer. Detachment is likely to occur here, and in the compressive-flow regime shortening by stacking and/or folding of debris sheets, and thereby creation of positive land forms, is to be expected. Reference Boulton, Price and SugdenBoulton (1972) discussed the possible entrainment of subglacial material at “feathering edges” of subglacial permafrost and attributed importance to possible high subglacial water pressures. Reference Moran, Clayton, Hooke, Fenton and AndriashekMoran and others (1980) described multi-crested ice-thrust land forms from the Prairie region in North America. They attributed them to stacking at a thawed/frozen-bed transition near a cold-based ice margin and, like Reference Boulton, Price and SugdenBoulton (1972), emphasized the role of high subglacial water pressures. The formation of an englacial debris structure at a warm/cold base transition in a small valley glacier was described by Reference Clarke and BlakeClarke and Blake (1991), who discussed several mechanisms (bulge formation in substratum, recumbent folding and thrust faulting) by which internal layers of basal sediments could form at such a basal transition. As the internal structure of the stoss-side ridges is unknown, we cannot at present be more precise than to state that they appear to be related to folding or thrusting of subglacial sediment in compressive-flow zones up-glacier of frozen-bed patches.

The lateral-sliding boundaries are the most frequent elements delineating frozen-bed patches (or sliding “holes” as at Fulufjället). Deformation of pre-existing features (Figs 9 and 10)in Reference Kleman and BorgströmKleman and Borgström (1990)) is direct evidence for strong shearing across such boundaries. We see a frozen/thawed bed boundary as the only reasonable explanation for such strong lateral shearing at the glacier bed. When, due to warming, the PCS rose and intersected the terrain, the former continuous terrain-conformable zone of strong shear, which would be present in the lower part of a fully cold-based ice sheet, was disrupted and sub-vertical shear zones developed close to the base at the sides of frozen patches. The development of an easy-glide fabric by crystal re-orientation in these vertical shear zones may be a mechanism whereby the locations of the lateral sides of sliding zones were self-stabilizing. The fact that lateral-sliding boundaries occasionally cut across the topographic grain, as at the Tjuolma site (Reference KlemanKleman, 1992), is a strong indication that properties in the ice govern the lateral location of the sliding zone. If the frozen-patch size is large relative to the ice thickness, then such shear zones can be expected to extend to the ice surface.

The lateral-shear moraines are features that may or may not be present at the lateral-sliding boundaries. The only examples of this feature yet known are the 0.6 km long Arvestuottar ridge and the 68 km long ridge described by Reference Dyke and MorrisDyke and Morris (1988) and Reference Dyke, Morris, Green and EnglandDyke and others (1992) from Prince of Wales Island, Arctic Canada. The Prince of Wales Island ridge appears to be strictly parallel to flow lines. The Arvestuottar ridge, however, is located on a part of the sliding boundary where flutings indicate flow at a small angle (3-5°) into the frozen patch. It can therefore be seen as an extreme case of an oblique stoss-end ridge, formed by highly skewed folding or thrusting in a compressive environment.

Discussion

We interpret the relict surfaces to have been subjected to uninterrupted frozen-bed conditions on the patches. Any time period of basal melting at these sites during the 20–50 ka life of the last ice sheet would, in all probability, have erased or buried delicate, relict land forms such as sorted polygons. Where a readily discernible relict landscape is lacking, identification of former frozen-bed patches will be difficult or impossible.

The thermal boundary forms described here separate “young” (last flow stage) forms from relict surfaces. Naturally, thermal boundary forms can also be relict. That is, they can separate two fossil landscapes of different ages. The lateral shear moraine described by Reference Dyke, Morris, Green and EnglandDyke and others (1992) separates two drumlin landscapes of different ages, with the late-glacial flow direction marked by a third, cross-cutting, flow-trace fan. Similarly, a transverse till scarp in the Transtrand mountains was excavated by Reference Kleman, Borgström, Robertsson and LilliesköldKleman and others (1992). The scarp was formed in a lower till unit and overlain by a uniformly thick late Weichselian basal till. Despite draping by a later till, this transverse-till scarp is still a prominent morphological feature.

The three areas we have described here (Figs 3, 5 and 7) indicate a basal-thermal patchiness on the 1-10km scale, with the location of frozen-bed zones governed mainly by the location of humps (individual mountains or large hills). Although the mapped areas are too small for any far-reaching conclusions, there appears to be a roughly 1: 1 relationship between humps and frozen patches. Using the terminology of Reference HughesHughes (1992), the Arvesuottar and Häggingfjället hill summits were “sticky frozen spots in a slippery thawed matrix”, while the Tangån and Tangåfjället patches were “slippery thawed spots in a sticky frozen matrix”. The three areas give direct geomorphological evidence that the patchy thermal conditions postulated by Reference Hughes, Denton and HughesHughes (1981, Reference Hughes1992) have existed under parts of a large ice sheet.

Geographical distribution of relict surfaces and regional basal conditions

We have identified about 20 well-defined, enclosed patches in medium-relief terrain, of which five are described in some detail here. However, relict land forms (tors, old meltwater channels and old felsenmeers) on interfluves between glacial troughs and less well-delineated relict surfaces are more common than the well-defined patches presented here. Most relict surfaces are located in a zone along the eastern flank of the Scandinavian mountains, in the northern part adjacent (Reference Kleman, Borgström, Robertsson and LilliesköldKleman, 1992) to the “Veiki” landscape described and dated by Reference LagerbäckLagerbäck (1988b). This landscape marks a very large (more than 50 000 km3) area of frozen-bed conditions.

The frozen-bed patches described are unlikely to have been stable features. They are instead interpreted as representing shrinking remnants of once continuous frozen-bed zones that in the north encompassed the eastern part of the mountains (Reference KlemanKleman, 1992) as well as all north-central Sweden. The conclusion that northern Sweden must have had regional frozen-bed conditions during the LGM and earlier flow phases of the late Weichselian is based on the fact that the dated early Weichselian landscape (Reference Lagerbäck and RobertssonLagerbäck and Robertsson, 1988) in north-central Sweden bears no flow traces from the time when the ice divide was centred over the Gulfof Bothnia. The alternative explanation, a LGM ice divide situated over the mountains northwest of Arvestuottar, can be excluded on the basis of the isostatic uplift pattern, the northward-trending Pajala drumlin fan (Reference KlemanKleman, 1990) and the extremely asymmetric ice sheet that would result. A core area of frozen bed in the southern part of the mountain chain is also indicated by relict surfaces and land forms (Reference Sollid and SörbelSollid and Sörbel, 1988; Reference Kleman and BorgströmKleman and Borgström, 1990; Reference Kleman, Borgström, Robertsson and LilliesköldKleman and others, 1992) but its extent is as yet unknown.

The changing-flow configuration of the ice sheet during the post-LGM stages (Reference KlemanKleman, 1992) gives some clues to the age of the patchy conditions at the Arvestuottar site. Ice flow during the LGM was westward from the main dome over the Gulf of Bothnia. During the decay phase, the ice divide migrated westward, over Arvestuottar, to a final position within the mountain range. The ice flow from the north-northwest at Arvestuottar is therefore linked to the decay phase (about ll-9ka), and is unlikely to have lasted more than 1-2 ka, possibly even less. The migration of the ice divide across the site towards the west suggests accelerating flow (as the ice divide moved away to the west) and increased release of deformation energy. Thinning and surface melting could also be responsible for some basal warming.

Consequences for paleo-ice-sheet models

Hitherto, there has been a consensus that striae, flutings and drumlins are positive evidence for a thawed bed but there has not been a similar consensus about criteria for discerning frozen-bed conditions. We suggest that the relict surfaces are considered positive evidence for frozen-bed conditions. We further suggest that the presence of thermal boundary forms, such as those described above, is taken as positive evidence for patchy thermal conditions during at least one interval of a glacial.

Models that calculate ice-sheet temperatures (Reference HookeHooke, 1977) can therefore be tested against reconstructions of bed conditions based on geological evidence. Time-dependent numerical ice-sheet models that require specification of either a sliding condition or a no-slip condition at every point of the bed (Reference Fastook and HolmlundFastook and Holmlund, 1994) can be improved by taking evidence for basal thermal conditions into account. At present, good input data are restricted to topography, while other input data are generally deduced through climatological arguments and broad assumptions regarding regional basal conditions and ice viscosity.

Relict surfaces that preserve evidence for existence of frozen-bed conditions can be expected to have been largely destroyed in inward-migrating thawed zones during deglaciation (Reference KlemanKleman, 1992). Therefore, interpretations based on maps of relict surfaces may substantially underestimate the extent of frozen bed that existed during earlier flow phases, and sensible extrapolations will have to be done.

Conclusions

Glacially truncated ice-overriden relict surfaces occur along the eastern margin of the Scandinavian mountains. They mark patches of former frozen bed during late stages of the last glaciation. These patches were shrinking remnants of larger frozen-bed zones in west-central and northern Sweden.

The proximal ends of frozen-bed patches are centred on hills but the sides cut across slopes along flow lines.

A distinct land-form assemblage at the edges of frozen-bed patches includes stoss-side moraines, lateral-sliding boundaries, lateral-shear moraines and transverse till scarps.

The formation of stoss-side moraines and transverse-till scarps occurs in two detachment zones where soil frozen to the glacier overlies thawed soil. The detachment zones are located where, due to warming, a rising phase-change surface (water/ice) intersects the soil layer up-and down-glacier from residual frozen-bed patches.

Identification of relict surfaces and land forms related to patchy basal thermal conditions can improve ice-sheet models by providing more realistic estimates of the extent of sliding.

Acknowledgements

This study was financed through grants from the Swedish Natural Science Research Council. We thank R. LeB. Hooke, N. Iverson, A. S. Dyke, B. Strömberg, S. Jonsson and С. Hättestrand for constructive comments on the manuscript.

The accuracy of references in the text and in this list is the responsibility of the authors, to whom queries should be addressed.

References

Andersen, B. G. and Mangerud, J. 1989. The last interglacial-glacial cycle in Scandinavia. Quaternary International, 3—4, 2129.CrossRefGoogle Scholar
Borgström,, I. 1989. Terrängformerna och den glaciala utvecklingen i de södra fjällen. Stockholm University. Department of Physical Geography: Mtddelande 234.Google Scholar
Boulton, G. S. 1972. The role of thermal regime in glacial sedimentation. In Price, R.J. and Sugden, D. E. Comps. Polar geomorphology. London, Institute of British Geographers, 119. (Special Publication 4.)Google Scholar
Carol, H. 1947. The formation of roches moutonnées. J. Glaciol., 1 (2), 5759.Google Scholar
Clarke, G. K. C and Blake, E.W. 1991. Geometric and thermal evolution of a surge-type glacier in its quiescent state: Trapridge Glacier, Yukon Territory, Canada, 1969–89. J. Glacial., 37 (125), 158169.Google Scholar
Denton, G. H. and Hughes, T.J. 1981. The last great ice sheets. New York, etc., John Wiley and Sons.Google Scholar
Dyke, A. S. 1983. Quaternary geology of Somerset Island, District of Franklin. Geol. Surv. Can. Mem. 404.Google Scholar
Dyke, A. S. and Morris, T. F. 1988. Drumlin fields, dispersal trains, and ice streams in Arctic Canada. Can. Geogr., 32 (1), 8690.CrossRefGoogle Scholar
Dyke, A.S., Morris, T.F. Green, D.E.C. and England, J. 1992. Quaternary geology of Prince of Wales Island, Arctic Canada. Geol. Surv. Can. Mem. 433.Google Scholar
Fastook, J. L. and Holmlund, P. 1994. A glaciological model of the Younger Dryas event in Scandinavia. J. Glacial., 40 (134), 125131.CrossRefGoogle Scholar
Goodman, D. J., King, G.C.P. Millar, D. H. M. and Robin, G. de Q. 1979. Pressure-melting effects in basal ice of temperate glaciers: laboratory studies and field observations under Glacier d’Argentière. J. Giaciol., 23 (89) 259271.Google Scholar
Hooke, R.LeB 1977. Basal temperatures in polar ice sheets: a qualitative review. Quat Res., 7 (1), 113.Google Scholar
Hughes, T. 1973. Glacial permafrost and Pleistocene ice ages. In North American Contribution. Permafrost. Second International Conference, 13-28 July 1973, Yakutsk, U.S.S.R. Washington, DC, National Academy of Sciences, 213223.Google Scholar
Hughes, T.J. 1981. Numerical reconstruction of paleo-ice sheets. In Denton, G. H. and Hughes, T.J. eds. The last great ice sheets. New York, etc., John Wiley and Sons, 221261.Google Scholar
Hughes, T.J. 1992. Abrupt climatic change related to unstable ice-sheet dynamics: towards a new paradigm. Palaeogeogr. Palaeoclimatol. Palaeoecol. (Global and Planetary Change Section), 97, 203234.CrossRefGoogle Scholar
Hutter, K. and Olunloyo, V. O. S. 1981. Basal stress concentrations due to abrupt changes in boundary conditions: a cause for high till concentration at the bottom of a glacier. Ann. Glaciol., 2, 2933.Google Scholar
Kleman, J. 1990. On the use of glacial striae for reconstruction of paleoice sheet flow patterns — with application to the Scandinavian ice sheet. Geogr. Ann., 72A (3-4), 217236.Google Scholar
Kleman, J. 1992. The palimpsest glacial landscape in northwestern Sweden — Late Weichselian deglaciation landforms and traces of older west-centered ice sheets. Geogr. Ann., 74A (4), 305325.Google Scholar
Kleman, J. and Borgström, I. 1990. The boulder fields of Mt. Fulufjället, west-central Sweden — Late Weichselian boulder blankets and interstadial periglacial phenomena. Geogr. Ann., 72A(1), 6378.Google Scholar
Kleman, J., Borgström, I. Robertsson, A.-M. and Lilliesköld, M. 1992. Morphology and stratigraphy from several deglaciations in the Transtrand mountains, western Sweden. Journal of Quaternary Science, 7, 117.CrossRefGoogle Scholar
Lagerbäck, R. 1988a. Periglacial phenomena in the wooded areas of northern Sweden — relicts from the Tärendö interstadial. Boreas, 17 (4), 487499.CrossRefGoogle Scholar
Lagerbäck, R. 1988b. The Veiki moraines in northern Sweden — widespread evidence of an Early Weichselian deglaciation. Boreas, 17 (4), 463486.Google Scholar
Lagerbäck, R. and Robertsson, A.M. 1988. Kettle holes — stratig-raphical archives for Weichselian geology and palaeoenvironment in northernmost Sweden. Boreas, 17 (4), 439468.Google Scholar
Lundqvist, J. 1992. Glacial stratigraphy in Sweden. In Kauranne, K., ed. Glacial stratigraphy, engineering geology and earth construction. Geol. Surv. Finl., Spec. Pap. 15, 4359.Google Scholar
Moran, S.R., Clayton, L. Hooke, R.LeB Fenton, M. M. and Andriashek, L.D. 1980. Glacier-bed landforms of the prairie region of North America. J. Glaciol., 25 (93), 45776.Google Scholar
Prest, V.K., Grant, D.R. and Rampton, V.N. 1968. Glacial map of Canada. Ottawa, Geological Survey of Canada. (Map 1253A.)Google Scholar
Rodhe, L. 1988. Glaciofluvial channels formed prior to the last deglaciation: examples from Swedish Lapland. Boreas, 17 (4), 511516.Google Scholar
Sollid, J. L. and Kristiansen, K. 1982. Hedmark Fylke, kvarttrgeologi og geomorfologi 1:250 000. Oslo, Oslo Universitet. Geografisk Institutt.Google Scholar
Sollid, J. L. and Sörbel, L. 1988. Utbredelsemönstret av glacialgeologiske former i Sör-Norge i lys av breens temperaturforhold. In 18 Nordiske Geologiske Vintermöde, Köbenhavn. Abstracts, 378379.Google Scholar
Sugden, D.E. 1978. Glacial erosion by the Laurcntide ice sheet. J. Glacial., 20 (83), 367391.Google Scholar
Sugden, D. E. and Watts, S. H. 1977. Tors, felsenmeer, and glaciation in northern Cumberland Peninsula, Baffin Island. Can. J. Earth Sci., 14 (12), 28172823.Google Scholar
Figure 0

Fig. 1. Location map. Numbers show location of sites mentioned in text. 1, Tjuolma; 2, Arvestuottar; 3, Långfället; 4, Städjan; 5, Häggingßället; 6, Fulufjället; 7, Transtrand.

Figure 1

Fig. 2. Map of the Arvestuottar area. The relict surfaces (A, B), marking the sites of former frozen-bed patches, are located on topographic highs and are elongated in the ice-flow direction. Boxes show locations of Figures 3 and 4. Moraine ridges (D,E) occur proximally and laterally to the relict surfaces.

Figure 2

Fig. 3. Vertical aerial photograph of a lateral sliding boundary (C) at Arvestuottar. The area to the left of the boundary bears patterned ground and lacks glacial flow features. It is interpreted as a relict (interstadial) surface, preserved by continuous frozen-bed conditions. The area to the right is fluted and lacks patterned ground.

Figure 3

Fig. 4. Stereogram of the stoss-side ridge (E) at Tourpun, Arvestuottar. The ridge is localedashort distance up-glacier from a relict surface. See Figure 2 for location.

Figure 4

Fig. 5. Map of the Häggingfjället area.

Figure 5

Fig. 6. Vertical aerial photograph of the eastern summit of Häggingfjället. The relict surface (C) is truncated by a cross-mountain till scarp.

Figure 6

Fig. 7. Map of the relict surfaces and sliding-bed zones (A, B, E) at Fulufjället. The down-glacier end of the fully enclosed sliding patch (B) is marked by an arcluate boulder ridge (C). The arcuate ridge (D) is interpreted to have an origin similar to (C) but has later been subjected to basal sliding and partial destruction.

Figure 7

Fig. 8. Vertical aerial photograph of the Tangåfjället and R. Tangån sliding zones, Fulufjället. See Figure 7 for interpretation.

Figure 8

Fig. 9. Relict surfaces at Fulufjället. These surfaces are characterized by boulder depressions and large sorted polygons. Such features are lacking in adjacent areas showing evidence of basal sliding.

Figure 9

Fig. 10. Five land forms characteristic of the frozen-bed patch environment shown on an idealized mountain. The four thermal boundary land forms are shown in the relative positions in which we have repeatedly identified them.

Figure 10

Fig. 11. This shows how a phase-change surface (PCS), that rises over time, creates two detachment zones where soil frozen to the glacier base overlies thawed soil or the soil/rock interface. The stoss-side ridges are thought to have formed by folding or stacking of debris sheets in front of frozen-bed patches, while the transverse till scarps mark the sites where debris sheets were entrained in an extending flow zone.