The area depicted in Figure 1 consists of plains that rise gently from sea level to an elevation of about 210 m in the west, although there are spot heights of 250 m. Below an elevation of 110 m, the land slopes uniformly at a rate of about 1 m/km. Above this elevation, relief is less regular, and rises at a rate closer to 3 m/km. The relief and substrate are controlled by deposits of the last glaciation and the postglacial period. Areas north of Seal River were covered by south-flowing glaciers that deposited a permeable sandy granitic till, while areas to the south were covered by ice from Hudson Bay that deposited less permeable silty, calcareous till. Relief features created by glaciers include small rib moraines north of Seal River, and larger, broad arcuate moraines, plus a few eskers farther south. The southwestern part of the region was later covered by Glacial Lake Agassiz, the water body that inundated the region as glaciers retreated. Lake Agassiz drained about 7800 radiocarbon years ago when the ice centre in Hudson Bay collapsed (Dredge and Nixon, 1992) leaving a layer of lake bed deposits of brown silt and clay. The rest of the area, which lies below an elevation of 140 m (the dashed line on Fig. 1), was initially inundated by the postglacial Tyrrell Sea. As the land rebounded from the glacial load, this sea regressed to its present position. Marine deposits, consisting of a sand layer underlain by silty clay or stony silt that filled in irregularities in the underlying topography, were exposed during marine regression. Raised beaches provide local relief, and a large raised beach complex built on an old moraine is a major landscape feature near the marine limit. The peatlands shown on Figure 1 correspond to the extensive areas of impermeable silty substrate that have low relief.

Radiocarbon dates on marine shells provide some control on the rate of land emergence at the sites in this paper. The sea level curve for this region (Dredge and Nixon, 1992) indicates that the Bradshaw site emerged 7800 radiocarbon years ago, as soon as Lake Agassiz drained, and the Thibaudeau, Silcox and Lost Moose sites emerged from the sea 7400, 7600 and 6800 radiocarbon years ago, respectively. These are the earliest possible dates for the beginning of vegetation growth and peat accumulation for the sites mentioned.

Churchill experiences a maritime subarctic climate with an annual mean daily air temperature of -7.3 °C. Daily means range from 12 ^oC for July to -27 ^oC for January. The frost-free period is 110 days. Precipitation averages 412 mm at Churchill airport, about 235 mm of which falls as rain. Prevailing winds are from the northwest, both in winter and summer, at an average velocity of 21 km/h (Environment Canada, 1982). The area is sufficiently cold that organic deposits do not readily decompose, but warm enough in summer to support healthy vegetation growth, and thus substantial peat accumulation over the region. The northeastern part of the area lies within the zone of continuous permafrost, with annual ground temperatures equilibrating at -4 ^oC in bedrock at Churchill, and at -1 ^oC in marine clay. Depth of thaw rarely exceeds 60 cm, particularly where dry peat is present. To the southwest, permafrost becomes discontinuous; where peat is dry and thick, permafrost is present, but it is absent where peat is thin or where there is standing water.

Regional descriptions of vegetation communities have been reported by Ritchie (1960a, b; 1962). Most of the area north of Seal River shown in Figure 1 is sparsely vegetated with subarctic herb-tundra communities. Farther south, the vegetation of the coastal area consists of wet meadows of grass and sedge. Moss-lichen-heath vegetation covers tundra areas inland from the coast (Kuhry, 1998). Clumps of stunted spruce cover small areas, and sedge is common along drainageways. An open shrub/scrub forest transition runs diagonally across the region, and an outlier with transition vegetation occupies the vicinity of Churchill. The isolated forest-tundra transition areas near Hudson Bay support patches of stunted forest, predominantly white spruce (Picea glauca), with some black spruce (P. mariana) and tamarack (Larix laricina) in wet areas (Rowe, 1972; Rouse et al., 1995). In the open shrub/scrub forest transition farther inland, trees are more abundant and show better growth, with forest cover increasing until closed forests prevail.

The vegetation of the southwestern part of the study area is boreal forest. Black spruce is the dominant species on peat-covered landscapes, along with tamarack, whereas white spruce characterizes better drained upland areas and river banks with better drainage. Better drained sites may support some balsam fir (Abies balsamea), trembling aspen (Populus tremuloides), balsam poplar (P. balsamifera) and white birch (Betula papyrifera). Among the shrubs, speckled alder (Alnus incana rugosa) and various species of willow (Salix spp.) are common, along with dwarf birch (B. glandulosa). Green alder (A. viridis crispa) occurs on some drier sites in the south and southwest. Sedges (Cyperaceae) and grasses (Gramineae) are common in sedge meadows and fens. An understory of Labrador tea-sphagnum-blueberry (Ledum-Sphagnum-Vaccinium) is widespread on peaty substrates.

For the regional mapping project (Dredge and Nixon, 1979a, b), peat was sampled using either a Hoffer coring device with a 2.5 cm core barrel, or a SIPRE (CRREL) power drill with an 8 cm diameter core barrel (Veillette and Nixon, 1980). The cores near the railway that are reported in this paper were drilled by Manitoba Hydro in 1984 with a SIPRE corer. The Bradshaw core, used for comparison, is from the earlier regional mapping project. The sediment stratigraphy of the cores was described by Manitoba Hydro when the cores were extruded. When subsamples for pollen analysis were removed several years later it was noted that some shrinkage had occurred, probably as a result of desiccation. Any discrepancy noted in the length of the cores at the time of subsampling was justified by relating the stratigraphy and subsampling position to the field measurements.

A 1 cm³ volume of peat determined by displacement of water in a graduated cylinder was used for all treatments, as the peaty sediments were too friable to otherwise measure a volume. A measured volume of exotic pollen (Eucalyptus globulus) suspension was added to each sample prior to treatment using a hypodermic syringe (Benninghoff, 1962). The concentration of the exotic mixture was determined by an haemacytometer as 102 700 grains/cm³. Chemical treatment of each sample involved digestion in concentrated hydrofluoric acid, 10 % potassium hydroxide, dilute hydrochloric acid (10 % and 50 %), dilute nitric acid (10 %) and acetolysis (a 9 : 1 ratio of acetic anhydride to sulphuric acid) followed by dehydration in tertiary butyl alcohol. The residue was stored in glass vials with silicone oil until microscopic analysis.

A minimum of 300 pollen grains and spores was identified and counted. Pollen percentages were calculated using a pollen sum (a minimum exceeding 100 grains) excluding Cyperaceae pollen and all spores, which were so high that they overwhelmed values of the other taxa used in interpretation. Pollen accumulation rates (PAR) were calculated based on the sum of the taxa used for percentage calculations, and the radiocarbon dates available for each site. Pollen diagrams were plotted using the programs TILIA and TILIAGRAPH (E. Grimm, Illinois State Museum, Springfield, Illinois).

Conventional radiocarbon dates on peat (5 or 10 cm increments) and wood included in this report were provided by the Geological Survey of Canada Geochronology Laboratory (Table I and pollen diagrams). All dates used throughout are in radiocarbon years BP The emergence times in Table I include a 400 year marine reservoir correction on normalized ages on marine shells.

Overall, peat cores taken during the regional mapping program were found to contain large amounts of dark brown fibrous sphagnum peat, with a layer of sedge peat and/or wood at the base. In polygonal peat plateau bogs, however, interlayers of sphagnum peat and amorphous, yellowish sedge peat were commonly encountered. The peat contained large amounts of segregated ice and ice coated particles, with a layer of massive ice 3-4 cm thick separating peat from mineral substrate.

Pollen accumulation rates throughout the region are much lower than those seen at mid-latitudes, indicating the depauperate nature of the flora. The PAR data further indicate that spruce trees were the dominant taxon in the region. However, without more chronological control, especially for more recent times, it is difficult to say whether or not spruce trees increased or declined at any one site. For instance, Bradshaw Lake bog site is presently within a forested landscape and yet pollen accumulation rates are similar to those at Thibaudeau and Lost Moose sites, which are in the forest/tundra transition where spruce trees are stunted and less abundant. Silcox site has low pollen accumulation rates in zones S-I and S-II even though Picea pollen dominates the profile. Relative Picea percentages decrease in the upper part of the profile where pollen accumulation rates increase. This is partly due to increased Ericaceae and Poaceae, but the rates suggest that spruce trees remained as abundant as in lower zones, or increased somewhat. In contrast, PARs at both Lost Moose and Thibaudeau sites are lower near the tops of the profiles, coincident with declines in Picea percentages.

All sites show an abundance of Picea pollen from the earliest dated interval, suggesting that spruce trees were the dominant tree taxon throughout approximately the last six millennia. Pinus pollen, which rarely exceeds 20 %, can be attributed to long distance transport. Pine trees do not occur in the immediate vicinity of any of the sites which have Pinus percentages of 12 % or less. The nearest occurrences of pine trees are on dry ridge sites 50 km to the southwest. Therefore, although Pinus percentages approaching or slightly exceeding 20 % may indicate that pine trees were nearer to the sites in the past, they never became abundant, even in the southern part of the region. Low peaks in Betula and generally low Betula percentages throughout the profiles suggest that birch trees were never abundant but occupied small sites when conditions were suitable. Dwarf birch (B. glandulosa) may also account for some of the Betula pollen, as birch species were not identified. The low levels of Alnus, probably A. incana rugosa (speckled alder), indicate that this species was probably only locally abundant in habitats similar to those it occupies today. Alnus species were not differentiated, and it is possible that A. viridis crispa (green alder) may have been present on the drier upland sites. Percentages of other arboreal taxa are minimal, and may represent long-distance dispersal. Poplar/aspen, fir and tamarack in particular were never abundant and probably had occurrences similar to those at present.

Various shrubs, particularly willow, were present locally in low abundance throughout the postglacial. One exception is heath plants, which show increased abundance at almost all sites in the last several hundred years. This abundance coincides with extremely high values for Sphagnum spores, indicating a shift to bog conditions as opposed to wetter fen environments which are characterized by abundant sedges and grasses. Thibaudeau and Lost Moose sites show these shifts particularly well. The pollen accumulation rates also suggest a shift to bog conditions, with a decline in spruce trees locally as bogs became more prevalent.

Peat deposits dominate the landscape in this region, but they differ greatly in thickness, as can be seen from the data presented here. In areas of continuous organic terrain, peat ranges to 400 cm in thickness. On a regional scale, fen peat is considerably thinner (maximum 1.5-2 m) than bog peat (2-4 m). As well as peat type, the substrate type, topography, and time available for peat growth are other factors controlling thickness. For each major peatland class shown on Figure 1, peat is thickest on impermeable silty till, on glaciolacustrine clay and marine silt, and where terrain is flattest; data acquired through mapping shows that peat is thinnest on moraines and other sloping terrain, and absent on eskers, raised beaches, and sandy till.

There is some relationship between peat thickness and elevation above sea level, a measure of time available for peat accumulation since land emergence, although there is a considerable amount of site to site variation apparent on Figure 8, most of which is due to topographic factors. Areas near the coast that lie below an elevation of 15 m emerged less than 1500 years ago (Dredge and Nixon, 1992), and do not have substantive peat deposits, with peat thicknesses varying between 0 and 10 cm. Peat in areas between elevations of 15, 30, 60 , and 90 m that emerged about 1500, 2500, 4500, and 6000 years ago respectively, have corresponding increases in peat thicknesses from 25 to 50 to 100 to 150 cm respectively. Average peat thicknesses between elevations of 120 m and 140 m, the upper limit of postglacial marine emergence in the study area, are generally slightly lower, possibly because drainage is better due to a greater slope of the land, and the presence of large beach-ridge complexes. Above 140 m, peat thickness varies greatly due to local slope changes on broad moraines underlying Glacial Lake Agassiz clays.

Flat fens are the dominant peat type on terrain below an elevation of 30 m (i.e., land that emerged less than 2500 years ago). Plateau bogs are common on older, higher terrain. This may be an areal expression of the same succession found in the vertical peat cores, discussed below. The time period for development of peat plateaus determined from the cores is similar to that proposed for development of bogs at Port Nelson (2000 years; Tarnocai, 1982), and the time of development of sphagnum bog at Herchmer (2200 years), although Kuhry (1998) attributed this change to climatic factors and permafrost development rather than to plant succession.

The peat cores show that time is only one of the factors controlling peat thickness. For instance, 160 cm of peat accumulated at the Thibaudeau site over a period of 6240 years, whereas 350 cm of peat accumulated at Bradshaw Lake bog over a similar period of time. These dated profiles indicate that peat type and rate of decomposition are also important; for example, at Bradshaw, fibrous moss peat predominates, whereas at Thibaudeau, more decomposed sedge peat comprises a considerable part of the core. When the peat accumulation rates on Figure 3 are compared to the pollen profiles, it is apparent that much faster rates of accumulation have occurred in the sphagnum peat than in the sedge peat. These findings are the opposite of those of Klinger and Short (1996), and Hilbert et al. (2000), who proposed faster accumulation rates in fens in their models for unfrozen peatlands, but the results of the present study are similar to those of Kuhry (1998) for this area, and for sites in northwestern Manitoba (Table I).

All sites studied emerged between 7800 radiocarbon years ago (Bradshaw site) and about 6600 years ago (Lost Moose site). Since the oldest basal peat ages are about 6300 years, it is possible that the oldest organic deposits were not recovered from the sites. Tarnocai (1982), for instance, suggested that peat is established within a period of 600 years from the time of emergence. The basal peat dates at M’Clintock, Fletcher Lake and Charlebois (Table I), also suggest peat development within the 600 year period. Nevertheless, although it seems improbable that pioneer vegetation did not invade the area for 1500 yrs after the land was exposed, the scarcity of peat within 15 m elevation of the modern shore shows that this time interval may be necessary for substantive peat deposits to accumulate.

The pollen profiles and the presence of wood in the basal sediments show that spruce trees were abundant in the region 6300 years ago and remained so to the present. Plant communities similar to those of the present also characterized the region throughout the entire time interval represented, with areas shifting from fen to bog as conditions changed locally. Areas covered by organic deposits must have increased as paludification continued over time. A change to bog from fen conditions in the last millennium is apparent in the pollen profiles for some sites as are increased accumulation rates seen in the age/depth curves (Fig. 3). This change could be attributed to natural vegetation succession, according to models proposed by Sjors (1963), Tarnocai (1982), and Klinger and Short (1996), among others. However, below this transition at Thibaudeau, Silcox, and Lost Moose, the shifts from fen to bog conditions seen in the pollen profiles and the age/depth curves are not consistent in sequence or timing from one core to another, suggesting that factors other than succession are acting here. Local changes in the water table may be particularly important (Hilbert et al., 2000). Although water table changes could theoretically be possible as a response to regional warming and melting of ground ice, or increased precipitation, the data suggests that the changes observed in the cores reflect more local factors. We suggest that the changes may be caused by local aggradation and degradation of ground ice, together with the development of collapse scar ponds, at different times. Aggradation of permafrost would raise peat surfaces above their local water table, and encourage bog development, while local melting of ground ice would create water-filled collapse scar depressions, promoting fens. Drainage or infilling of the thermokarst ponds, effectively lowering the water table, would cause a reversion to bog conditions. Also, what appears to be widespread changes may reflect a bias in sampling bog areas rather than wet fens, which cannot be traversed.

No changes in tree line, expected due to Nichols’ conclusions based on sites farther north at Ennadai Lake (Nichols, 1967; Fig. 1), are apparent from the profiles, even though tree line presently passes through the region. It is possible that vegetation zonation from tundra to boreal forest in this region is controlled by its proximity to Hudson Bay and not to regional continental Arctic air mass movements, as suggested for the tree line changes farther north and inland (Nichols, 1967; MacDonald et al., 1993).