Fluted till, striae, chattermarks, roches moutonnées and drumlins indicate a general westward (270°) flow that correspond to the regional ice flow reported in Parent et al. (1995). Flutings are located >200 m asl and concentrated in the NE sector of the study area, although some are present north of Rivière du Nord (Fig. 4). They occur in sectors where the Tyrrell Sea waters did not invade the land, and above marine limit in areas where it did (Figs. 4, 5). Bedrock outcrops exposing fresh and intact striae and associated erosion features are relatively rare since they were either eroded by periglacial coastal processes, affected by weathering or buried by Holocene sediments.

Temporary stabilization phases of the ice margin are recorded by ice-contact landforms and sediments. These ice front stillstands occurred in marine and terrestrial environments and led to the construction of frontal, ablation and marine DeGeer moraines as well as ice-contact glaciomarine and glaciofluvial sediment bodies. The distribution of these features is almost exclusively restricted to sectors of relatively higher relief (Fig. 4). Frontal moraines are generally parallel to sub-parallel to the actual seashore and occur on some summits of the Nastapoka Hills, where they are clearly visible above marine limit. Frontal moraines also occur in the bottom of a wide erosion gully in a sandur-delta (S44) and near the downstream portion of an esker in the southeastern part of the area (Fig. 4). Grounding lines and morainal banks occur in a general north-south trend along the Nastapoka Hills and form a distinctive mark between sandy sediments westward and silty-clay sediments eastward.

Ablation till consists of sub-angular to sub-rounded boulders and gravel with a very thin and irregularly distributed blanket of poorly sorted sand. Boulder and gravel often lie directly on glacially moulded bedrock outcrops. Generally, the finer-grained material veneer locally smoothes the landscape by filling out small depressions in bedrock. This moraine was deposited in the ice marginal zone as the ice sheet was retreating. It occurs on most hilltops of the Nastapoka Hills and is almost completely eroded and reworked below the marine washing zone, which forms a clear distinctive mark of marine limit.

DeGeer moraines were observed at 180 m asl and ~15 km north-east of the Rivière Nastapoka mouth. They are oriented parallel to the coast of Hudson Bay. As the marine limit in this sector is ~200-210 m asl, these moraines were formed under ~30 m of water. The mean spacing of 108 m between the ridges (Allard and Seguin, 1985), if taken as the yearly amount of retreat of the ice front, would suggest that it took ~330 yr for the ice front to retreat from the Nastapoka Hills to the inner limit of the marine transgression, some 35 km inland. This rate is less than the 150 m and 217 m/yr measured further south in the James Bay area by Vincent (1977). This slower rate of retreat for the Nastapoka sector can be attributed to more pronounced local topographic variations, marked by deep valleys and hills higher than marine limit (Allard and Seguin, 1985).

Ice-contact glaciomarine sediment accumulations occur as submarine fans, sandur-deltas and deltas. These predominantly sandy bodies were constructed near the ice front during stabilization phases of the eastward retreating ice margin. These deposits form two drift belts: one along the Nastapoka Hills range and the other at the inner limit of marine inundation on the Hudsonian Plateau (Fig. 4). The first belt consists of ice-contact submarine fans that were deposited in a glaciomarine sedimentary environment during a period of high RSL (Lajeunesse and Allard, 2002) and a pause in ice recession (Lajeunesse and Allard, 2003). Some fans become coalescent and form aprons ~5 km wide on the western slopes of the Nastapoka Hills. In many cases, sediments composing these fans are constricted in elongated bedrock basins and become coalescent downslope. The fans start upstream at ~200-220 m asl along the hill range (Lajeunesse and Allard, 2002) and slope down to below the present day sea level underneath Hudson Bay waters (Lavoie et al., 2002). Holocene gully erosion has exposed >20 m of sand, silt, gravel beds containing abundant fossil shells. High energy jets of glacial meltwater carved large potholes of 1-1.5 m of diameter and 2-3 m deep in bedrock side-walls.

The second drift belt consists of ice-contact sandur-deltas located in the eastern part of the study area (Fig. 4). They are located at 195-205 m asl and are associated with both the marine limit and the inland postglacial marine overlap zone. Sediments composing sandur-deltas were deposited in both subaerial and submarine environments and contain topsets, foresets and bottomsets. The subaerial sandurs bear networks of braided channels. The length of the outwash extends on more than 12 km in some cases and are often pitted with kettles. Many sandur-deltas are located at the downstream end of long and sinuous eskers indicating a flow from east to west. A cross-section analysed in S44 located in the downstream sector of a sandur-delta exposes predominantly undisturbed fine sand and silt beds deposited by suspension-settling. Sediment deformation and minor loading structures occur, indicating rapid sedimentation. There are no fossil shells at this site, which can be attributed to high inputs of fresh water in a restrained embayment. The distance between two moraines of the DeGeer type buried under this section indicates a very slow glacial retreat of 15-20 m/yr, i.e. a near stillstand. This second drift belt either marks a pause or a drastic slowdown of glacial retreat as the glacier front became separated from the effect of sea waters. Mass wasting became regulated only by melt without any influence of calving.

Marine limit is at 248 m asl near the Rivière Nastapoka mouth, ~220-227 m asl north of Rivière Nastapoka and 230 m asl at Rivière Devaux (Fig. 5). East of the Nastapoka Hills, the plane of the marine limit slopes down to 204 m asl at the maximum inland reach of the Tyrrell Sea where it forms an irregular paleo-coastline pattern (Allard and Seguin, 1985). Marine invasion went as far as 56 km inland from the present day coastline at Lac Kakiattualuk, 48 km along Rivière Nastapoka, 23 km along Rivière Devaux and 67 km in the southern portion of the study area in the depression of Lac Guillaume-Delisle.

Postglacial emergence is recorded by boulder ridges and pavements, raised beaches, perched deltas and terraces as well as coastal gelifraction of bedrock. Boulder ridges and pavements occur at any elevation below marine limit. Between 248 and 200 m asl, where bedrock has absolutely no cover of fines, they represent, together with gelifracted outcrops, the main geomorphic record of land emergence. Boulder ridges generally form series of linear or lightly curved ridges on sidewalls of small valleys. Boulder pavements occur on flat or gently sloping surfaces. Coastal periglacial erosion features (i.e. landforms made by frost-riving and ice-push processes on the shore) can be found up to the very marine limit. Below this limit, the smooth glacially moulded surface of bedrock was intensely disrupted by frost action in a wet coastal environment into angular clasts which were then carried away by drift ice and storm waves (Allard and Tremblay, 1983b). A large number of these clasts are present in boulder barricades and pavements and are mixed with subrounded allochtonous clasts derived from the washing out of glacial drift (Dionne, 1978). Coastal periglacial processes are still active along the present day shoreline. Series of beach ridges occur below 200 m asl, where they often form almost regular staircases in sand deposits. Vertical spacing between these ridges ranges from 2 to 7 m, as in the Lac Guillaume-Delisle region, just south of the study area (Hillaire-Marcel, 1976). These ridges are common features on the surface of the emerged deposits of the western slopes of the Nastapoka Hills. At least 60 beach crests occur between 0 and 100 m asl on a distance of 2.5 km near the Rivière Nastapoka mouth.

With the exception of till and moraines, Late Quaternary sediments of the study area record depositional and reworking processes that took place during the initial phase of marine transgression and the subsequent falling RSL. Sediments exposed in sections were deposited in ice-proximal (De1) and ice-distal (De2) glaciomarine, paraglacial (Pa) and emergence (Em) depositional environments (Tabl. II; Fig. 6). De1 deposits are associated with the two stillstands of the ice front (Nastapoka Hills glaciomarine fan complex and sandur-delta belt), De2 sediments are associated with the retreat between these two ice front positions. Pa sediments are associated with fluvial erosion and sedimentation as rivers made new courses by down-cutting and re-depositing existing sediments. A coarsening upward sequence representing the Holocene falling RSL is observed in most sections.

Fossil shells and driftwood buried under marine or coastal sediments provide maximum ages for the emergence of their overlying material whereas paleosoils, wood and peat buried by eolian processes or organic accumulation provide minimum ages for emergence. Hence, radiocarbon ages on shells and driftwood are located below the RSL curve while those from paleosoils, terrestrial wood and peat are above it. The assemblages of fossil shells recovered are not typical of the shore zone and the emergence facies are not fossiliferous; therefore no single raised beach or shoreline could be dated, such as what was done on the Manitounuk Islands, south of the study area (Allard and Tremblay, 1983a). The available data allows only a constrained RSL curve to be deducted (Fig. 8).

The RSL curve is characterized by an inflection between 5 and 6 ka cal. BP. This inflection indicates that the emergence occurred in an abruptly decelerating mode and divides the curve into three phases: 1) before 6 ka cal. BP; 2) between 6 and 5 ka cal. BP; and 3) after 5 ka cal. BP. Most fossils shells reported in this study were recovered in sediments deposited or remobilized by submarine mass movements before 6.5 ka cal. BP. A very important part of the 248 m total Holocene emergence took place in the first phase of glacioisostatic rebound.

After reaching a maximum elevation of 248 m asl about 8.3 ka cal. BP in the Nastapoka Hills, the Tyrrell Sea regressed rapidly at a rate of ~7 m/100 yr during deglaciation. This initial uplift rate is similar to the previously reported maximum rate of 6 m/100 yr on Ottawa Islands by Andrews and Falconer (1969). This emergence was accompanied by extensive and numerous submarine gravity flows on the steep slopes of ice-contact submarine fans located on the structural slope west of the Nastapoka Hills. These events cannot be directly attributed to postglacial seismicity linked to glacioisostatic recovery since they occurred in a setting prone to mass-movements (Lajeunesse and Allard, 2002). Slope instabilities in soft sediments, possibly triggered by bottom wave disturbances in shallowing waters might have been a key factor for submarine landslides during this phase. Following this period of homogeneous uplift rates (upper segment of the RSL curve), emergence decelerated to reach rates of ~4 m/100 yr between 6 and 5 ka cal. BP (inflection segment of the curve). This phase was characterized by a period of vegetation development on emerged sediments, in accordance with the timing of forest-tundra colonisation inland (Payette, 1983). Since 5 ka cal. BP, ~85 m of uplift has occurred at rates of ~1.7 m/100 yr (lower segment of the curve). Our data suggest an emergence rate slightly slowing down to ~1.6 m/100 yr over the last 1000 years, which is higher that the 1.3-1.5 cm/yr at Manitounouk Islands (Allard and Tremblay, 1983a; Bégin et al., 1993), 1.4 cm/yr near Inukjuak (Gray et al., 1993) and 1.1 cm/yr at Lac Guillaume-Delisle (Hillaire-Marcel, 1976). However, more dates are needed on this segment of the curve in order to improve the resolution of the recent uplift rate.

Land emergence led to extensive incision by rivers and streams through sand and silty clay deposits, which remobilized and carried downstream important volumes of sediments. RSL fall exposed marine sediments deposited during the deglaciation to the action of coastal processes. Exposed bedrock outcrops were disrupted by gelifraction; ensuing large rock fragments were redistributed by drift ice and added to glacial erratics to form boulder pavements and ridges. Accumulations of sand deposits were reworked by swash-and-backswash and eolian processes to form successive beach ridges. The upper portion of emergence deposits was reworked by eolian processes that formed dunes and deflation surfaces. During the late phases of emergence, the sedimentary regime of the Rivière Nastapoka was strongly affected by the formation of two important falls near the hill range. These bedrock sills formed inland basins that restrained coarse material from reaching the seashore and reduced greatly sand transport to the Rivière Nastapoka mouth (Lavoie, 2000; Lavoie et al., 2002). Ice-distal glaciomarine silty clay (De2), which was previously buried under deltaic deposits, will probably be the predominant sediment emerging in the future.

Considering the very important postglacial emergence of the area (~250 m) and the very high rates of regression still prevailing today (~8.3 ka cal. BP following deglaciation), it is questionable if this uplift can be attributed totally to glacioisostasy. In fact, an abnormally cold and dense downwelling convective region in the earth’s mantle located below the North American craton (Mitrovica, 1997; Simons and Hager, 1997) may have partially acted to depress the earth’s crust and/or contributed to create a sensitive zone for isostatic depression during the last glaciation.

Geomorphic, sedimentary and radiometric data indicate that deglaciation of the Rivière Nastapoka area was marked by four phases. During Phase 1, an ice stillstand occurred at 8.3 ka cal. BP along the Nastapoka Hills after a period of very rapid down-wasting and collapse over Hudson Bay (Lajeunesse and Allard, 2003). Large ice-contact glaciomarine fans were laid from the hills on the sea bottom, where now extends the coastal slope. At that time, theTyrrell Sea was at its maximum elevation and the emergence rate was extremely rapid. Sedimentation was dominated by suspension-settling from turbid glacial meltwater outflows, submarine gravity flows and ice rafting (Lajeunesse and Allard, 2002).

Phase 2 was marked by the unpinning of the ice front from the Nastapoka Hills and its rapid eastward retreat in the low elevation inner basin to the easternmost reaches of the Tyrrell Sea, about 35 km inland. This distance, together with the rate of retreat of 108 m/yr suggested by the DeGeer moraines, indicate that this phase lasted for 330 years. At the end of this phase, RSL had dropped to about 200-190 m asl. The high RSL in this deep basin exerted an important control on the glacial margin by promoting high rates of calving and fast ice flow and thus favouring ice sheet collapse and drawdown (e.g., Hugues, 1987; McCabe et al., 1993). Sedimentation was dominated by glacial meltwater outflows that deposited a thick silty clay drape from suspension-settling in submerged fjord-like valleys. During this period, the ice-contact glaciomarine fans of the Nastapoka Hills complex were intensively affected by submarine landslides. Timing control of this phase from radiocarbon dates is needed. However, considering that the end of Phase 2 sedimentation occurred in a RSL of ~200-190 m, it can be deducted from the uplift curve (Fig. 8) that this phase occurred prior to ~7.5 ka cal. BP.

Phase 3 was characterized by a second temporary pause or slowdown in ice retreat at the eastern margin of the Tyrrell Sea invasion, where elevations are slightly higher than in the inner basin. This phase began when RSL was still ~200-190 m asl, i.e. prior to ~7.5 ka cal. BP. The topography of this part of the study area and the rapid RSL fall caused this stabilisation by allowing the ice margin to become terrestrial, thus considerably reducing its ablation rate in shallower marine waters at the terminus. This phase lead to the deposition of a second regional drift belt consisting of sandur-deltas in association with important esker systems characterized by the same direction of flow than major rivers. Deposition of this sediment belt corresponds to either a complete stillstand of the ice margin or a change in sedimentation regime when the ice margin changed from a tidewater to a terrestrial environment. Sedimentation was dominated by glaciofluvial processes on the surface of sandurs and by turbid plumes in their submerged zones that deposited ice-proximal sand and silt. These plumes transported fines westward from these glaciofluvial systems and deposited silty clay along the fjord-like bedrock basins. According to shells recovered in De2 east of the Nastapoka Hills, ice-distal sedimentation continued until at least 7240 cal. yr BP (UQ-545). There is no evidence in support of a complete belt of ice recession for a set period on the Hudsonian Plateau. However, some far inland sectors were ice free at 6.6 ka cal. BP since organic remains had by then begun to accumulate in alluvial deposits over clay in the Rivière Sheldrake basin (Allard and Seguin, 1985). This phase was also early characterized by the development of a discontinuous permafrost (Allard and Seguin, 1987) and periglacial landforms (Lajeunesse, 2000).

Phase 4 was associated with the complete retreat of the ice margin from the area and its terrestrial ablation inland. Although the ice terminus was distant during this phase, sedimentation dynamics were still controlled by meltwaters. Sedimentation was dominated by fluvial processes that transported large amounts of glacigenic material along major river systems, which is typical of paraglacial sedimentary environments (Church and Ryder, 1972; Syvitski, 1993). During this period, sediment delivery was essentially controlled by river downcutting through pre-existing emerged deposits. Within the inner basin and where silty clay deposits are present, elevations of the third segment of the Rivière Nastapoka upstream from the second falls are between 125 and 160 m asl. This implies that the RSL was probably <160 m asl, considering that paraglacial deposits do not occur along the upper sections of Rivière Nastapoka. At the mouth of the paleo-Rivière Nastapoka, a thick and extensive fan delta developed <100 m asl. The RSL fall also lead to the incision, erosion and remobilization of ice-proximal and ice-distal glaciomarine and glacial sediments located along the fluvial system. These sediments were transported and deposited near the actual Rivière Nastapoka mouth as well as near other less important river mouths when the ice margin was tens and probably hundreds of kilometres distant. According to wood fragments (UL-1556) recovered in a fossil rich Pa1 bed, paraglacial sedimentation had already begun in some valleys by 5760 cal. yr BP. The fact that this rich fossil bed is overlain by more than 19 m of deposits points out abnormally high sedimentation rates that prevailed during this period, which is not representative of typical postglacial sedimentation conditions in Hudson Bay (Josenhans et al., 1988). This considerable sedimentation is attributed to the disintegration of Québec-Labrador ice and sediment reworking. Deposits similar to those reported here have been observed near the mouth of Grande Rivière de la Baleine (Gonthier et al., 1993).