Late Wisconsinan events in the area corresponding to the contemporary Humber River drainage basin played a significant role in landscape evolution and had long-lasting effects on valley morphology in the basin. In particular, topographic and sedimentary characteristics in the area of the Oak Ridges Moraine may have had a prominent influence on the fluvial activity of melt-water during deglaciation. Water at the melting edges of the Laurentide Ice Sheet tended to form large proglacial lakes, and their topographic confinement was accentuated by isostatic depression. However, the effects of these glacial lakes may not be completely understood simply by their extent and the location of their outlet. Initial fluvial processes occurring on deglaciated surfaces would have responded to the dynamic atmospheric and hydrogeologic conditions driven by such large amounts of ponded water.

As the Laurentide continental ice sheet retreated from southern Ontario, the action of ice lobes resulted in the formation of moraines and the impoundment of proglacial lakes. Evidence of these proglacial lakes is recorded not only in sediments, but also in many exposed shoreline bluffs throughout the Great Lakes region (Terasmae, 1980; Chapman and Putnam, 1984; Sly and Prior, 1984; Anderson and Lewis, 1985; Muller and Prest, 1985). Interpretation of deglacial and post-glacial events is complicated by shoreline identification and radiocarbon (¹⁴C) dating techniques; however, the most significant challenge is associated with the patterns and rates of isostatic rebound. This makes correlation of basin and regional water levels difficult, as the only true reference point is the centre of the earth. Despite these uncertainties, regional post-glacial events would have implications for patterns of fluvial erosion and drainage over newly exposed basin surfaces. Late Wisconsinan deglaciation in the Lake Ontario basin is characterized by events such as the formation of the Oak Ridges Moraine and the impoundment of glacial Lake Iroquois (Fig. 1); however, these events are also associated with other deglaciation activities in Southern Ontario.

As the Oak Ridges Moraine was formed, deposition between these lobes left behind a complex stratigraphy of sediments, which may also have been influenced by melt-water ponding between the lobes and the Niagara Escarpment at the western edge (Duckworth, 1979; Chapman and Putnam, 1984; Chapman, 1985). Described as an interlobate moraine, the stratified moraine complex is thought to have formed over a number of stages, with a sequence from subglacial sedimentation, to subaqueous fan and delta sedimentation, to ice-marginal sedimentation (Chapman, 1985; Barnett et al. 1998). The resulting feature is a topographic high extending approximately 160 km east to west and acting as a drainage divide between present day Lake Ontario and drainage to the north (Barnett et al., 1998).

Models of Lake Ontario post-glacial water levels (Fig. 2) have been proposed by Sly and Prior (1984) and Anderson and Lewis (1985). The main stage of Lake Iroquois was about 40 to 45 m above contemporary lake levels. At the west end of the basin, water levels during the falling stages of Lake Iroquois may have reached as much as 100 to 125 m below present day lake level (Sly and Prior, 1984; Anderson and Lewis, 1985). Rising water levels of early Lake Ontario between ca. 11 500 and 5000 ¹⁴C BP are generally associated with greater isostatic rebound at the basin’s eastern outlets (Anderson and Lewis, 1985). With the exception of the Nipissing Food phase (ca. 5000 to 4000 ¹⁴C BP), Lake Ontario water level continued to rise to the present day elevation (Anderson and Lewis, 1985).

These post-glacial events will be examined further in the context of the Humber River basin, a sub-basin of the contemporary Lake Ontario basin. Observations of valley morphology using a DEM and of incision chronology using radiocarbon dates will be used to investigate valley evolution in the Humber River basin. Although an accurate knowledge of the processes and events which formed these valleys would require a more intense research design, observations made in this study may provide insight, and perhaps guide future research questions.

The present day Humber River basin, a sub-basin of the greater Lake Ontario basin, drains an area of about 900 km² at the northwest end of the lake. With headwaters beginning on the Oak Ridges Moraine, the Humber River and the East Humber River converge and flow south through incised valleys to their confluence (Fig. 3). These incised valleys generally follow a winding course, at times cut 30 to 50 m below the surrounding uplands. The valleys also appear to have a complex erosional history with many river terraces and valley widths ranging from 500 to 1 000 m. At the confluence, the main branch of the Humber River then continues to flow south through a narrow incised valley (width generally less than 200 m) before emptying into Lake Ontario.

Surficial geology within the basin is dominated by moraine sediments, glacial tills, and glacial lacustrine deposits left by the receding ice sheet (Sharpe et al. 1999). The younger surface tills (e.g. Halton Till) overlie older tills and sediments (e.g. Newmarket Till) which in turn overlie bedrock. The narrow incised valley of the lower Humber River is at times cut through the overburden, exposing the underlying Paleozoic shales (Chapman and Putnam, 1984).

As the incised valleys of the Humber River and East Humber River above the confluence exhibit complex erosional histories, they presumably possess the most information about their post-glacial evolution. Three field sites were selected along the East Humber River near Kleinburg, Ontario (Fig. 3), based on the occurrence of multiple terraces and abandoned channels. East Humber Valley 1 (EHV1) is located upstream of Kleinburg, East Humber Valley 2 (EHV2) is located at Kleinburg, and East Humber Valley 3 (EHV3) is located downstream of Kleinburg.

In order to assess the evolution of river valleys in the Humber River basin, this study combines analysis of digital elevation models (DEM), topographic maps, surface geology maps, and field data. Surface geology data were obtained from the Geological Survey of Canada (Sharpe et al., 2001). Field work at all study sites included stratigraphic description, radiocarbon sampling, and topographic surveys. Field surveys included valley geometry and terrace elevations for reference to maps and other digital geospatial data. Aerial photography was used in the format of digital orthophotographs for interpretation of features and site characteristics.

Digital elevation models (DEM) represent the landscape using a grid of 10 by 10 m cells which are assigned a value for elevation above sea level in 1 m intervals. Initial investigation of the DEM allowed for qualitative assessment of valley characteristics and morphology. Distance measurements, slope analysis, valley delineation, and river terrace identification were then performed using the DEM, orthophotography, and field survey results. As a generalization of the landscape, the vertical scale of the DEM was not adequate to represent floodplain morphology (e.g. terraces) within a few metres of the valley floor. For this reason field surveys and aerial photography were necessary to verify and supplement the DEM information. In addition to mapping of the valleys, the DEM was used in combination with drainage networks to collect information such as drainage areas and measurements of valley features (e.g. valley meanders).

Measurements of valley loop diameters was performed by manually fitting circles to the features. The circles were fit to the base of slope along the valley wall, which was identified using a slope analysis within the DEM. The diameter of curvature results were then statistically plotted against contemporary drainage area. To smooth out some variation in the data points, the valley loop data was also tested based on clusters of loop features which were given a common drainage area.

Terrace features were mapped and longitudinal profiles developed using the DEM, orthophotography, and field surveys. Following terrace identification, valley cross-sections were then extracted from the DEM and, in some cases, verified with a field survey. If terrace features were not flat, an average surface elevation was extracted from the DEM. The distances along a valley centre line were then mapped and extracted using the orthophotography and DEM.

Radiocarbon samples were collected from each field site to investigate valley incision chronology. Methods and interpretations regarding radiocarbon samples are summarized in Table I. Generally organic matter was extracted from alluvial deposits and chronological interpretations could then be based on the sample’s location relative to the geomorphic features of the site. Unless otherwise noted all dates are given in uncalibrated radiocarbon ages and have not been used to calculate absolute rates.

Valley evolution in the Humber River basin is generally characterized by initially rapid incision into the post-glacial landscape, with much less incision through the late Holocene (Fig. 9). Based on the character of valley evolution investigated in this study, and the established interpretation of post-glacial events, some general observations can be made which may account for the valley geomorphology observed today.

Interpretation of valley evolution in the Humber River basin can be achieved by looking at the rough chronological correlation between post-glacial events and inferred fluvial processes. Figure 12 illustrates a schematic representation of the postglacial incision in the Humber River basin identified in this study, and the associated deglaciation events and dates presented in the literature. Although there is still some uncertainty in the chronology of the events presented, the scale of the relationships illustrated here may still allow for some acceptable observations.

River valleys within the contemporary Humber River basin likely did not exist prior to the last glaciation; thus, the key event to begin this account is the formation of the Oak Ridges interlobate moraine between 15 000 and 13 000 ¹⁴C BP. As the Lake Ontario lobe of the ice sheet retreated eastward, much of the landscape of the contemporary Humber River basin would have been uncovered. Given the general scale and pattern of postglacial rebound, this area was still likely characterized by a topographic high at the Oak Ridges Moraine. As well, surficial geology was characterized by a complex stratigraphy of basal till, glaciolacustrine clays, and glaciofluvial deposits on the south slope. As this surface exposure persisted, processes of fluvial erosion and stream channel initiation would have begun to carve up the landscape. Based on the observations of valley morphology from the DEM, the channel pattern appears to have been initially characterized by sinuous meandering into the exposed glaciogenic deposits.

During the establishment and existence of Lake Iroquois in the Lake Ontario basin, ice retreat north of the Oak Ridges Moraine was also occurring and was associated with the development and existence of glacial Lakes Schomberg and Algonquin. These proglacial lakes are generally associated with the Huron basin; however, it is thought that lake levels submerged many areas north of the Oak Ridges Moraine and surrounding present day Lake Simcoe (Fig. 1). Despite considerations for isostatic depression by the Laurentide Ice Sheet and patterns of glacial rebound, raised water levels in this area would generally have been at a higher elevation compared to water levels in the Lake Ontario basin. This is supported by evidence of drainage from Lake Algonquin to the Ontario basin (Chapman and Putnam, 1984). Based on this fact, infiltration and groundwater flux patterns would have been characterized by flow through the complex stratigraphy to the south, some of it likely associated with Oak Ridges Moraine sediments. This pattern of hydraulic head would have interesting implications for baseflow and stream-flow patterns on the south slopes of the moraine.

The scale of meandering forms measured from the DEM (Fig. 6) suggest that paleochannels were much larger during initial incision. If the ancestral rivers in the Humber River basin were indeed much larger than today, this would require greater sources of water. Given the distribution of surficial accumulations of moraine sediments, it is also possible that northern ice was positioned at the moraine for some period of time following the withdrawal of the Ontario basin lobe to the south. Thus, initial fluvial incision south of the moraine could have been driven by melt-water directly from the melting edges of the northern ice; however, it is unclear if the timing and formative history of the moraine support this suggestion. It is also unclear if this can explain the character and timing of valley evolution.

Further melting and ice retreat north of the moraine generally resulted in melt-water collection by proglacial lakes, but there is little topographic or sedimentary evidence that overspill to the south was a significant process. There is some minor evidence of overspill in the surficial sediments just northeast of Nobleton (see Fig. 3 for location) and it has been speculated that some overspill at the moraine may have occurred near Palgrave (Eschman and Karrow, 1985); however, if overspill was a dominant factor in valley formation on the south slope, then headwater valleys should extend over the moraine. Overspill channels do not appear to be the dominant source of melt-water controlling valley evolution. Further, the direct contribution of significant melt-water to the drainage systems is not supported by the increasing size of valley features downstream. The melting front of a glacier or even a proglacial lake would be expected to deliver water independent of drainage area.

Instead, the increasing size of valley loops with increasing drainage area (Fig. 5) suggests that melt-water may have also indirectly supplied water to the Humber River basin by way of atmospheric or hydrogeologic sources. It seems logical that large accumulations of impounded water in the region would have moistened the atmosphere and induced significant groundwater flow through conductive sediments. While deeper hydrostratigraphy would have been involved, some of this groundwater flow would be associated with the Oak Ridges Moraine sediments. Moraine sediments are also associated with the in-filling of large sub-glacially formed channels (i.e. tunnel valleys), and moraine sediments have been documented at depths of 150 m, where the base may be lower than 130 m above sea level (Barnett et al. 1998). Referring to Figure 13, both main branches with the unique valley morphology originate from areas with significant moraine deposition. As well, the area of contemporary drainage between the two primary headwaters is an area where moraine deposition was not as significant. Consequently, this area also may not have contributed water as effectively during initial post-glacial incision, as suggested in Figure 5. Along the Humber River valley, there are two groups of valley loop data separated by a sudden increase in drainage area which seems to leave the data disjointed (Fig. 5A). This pattern suggests that the contemporary drainage area, which contributes to this jump in drainage area, was a much less effective source of water during the formation of the these valley features.

Moraine sediments tend to consist of coarser material than the till and lacustrine deposits, and thus are generally more hydraulically conductive. Further, the fine texture and density of basal till and glaciolacustrine deposits impart lower hydraulic conductivities. Thus, the spatial association of headwater drainage, valley morphology, and moraine sediments suggests that a major source of water to the ancestral rivers may indeed have been supplied by pro-glacial lake levels to the north driving groundwater flux to the south slopes. Additional evidence of this relationship with the basin hydrostratigraphy is the contemporary drainage network surveys performed by Hinton et al. (1998) which show that most river baseflow in the basin is associated with moraine sediments.

Given the significant geomorphic effects of early river evolution compared to contemporary processes, it is logical to presume that paleorivers were more competent with regard to eroding and transporting sediment. Although river hydrology is an important factor, the character and supply of the sediment may also play a role in changing river competence through the course of river evolution. As much of the postglacial surface was characterized by a stratigraphic sequence of various glaciogenic materials, initial incision was likely associated with relatively young sediments, with potentially abundant silt and sand sized materials. In contrast, it is possible that late Holocene rivers have been eroding older, perhaps more resistant, deposits, and have suffered from a concentration of coarser material (e.g. till clasts) within the valley fill. This process is also suggested by the highly controlled and irregular meandering exhibited by the contemporary river channels.

Following the drainage of glacial Lake Iroquois after 12 000 ¹⁴C BP, surfaces previously below the level of Lake Iroquois would have been exposed to the fluvial incision from the established drainage upstream. As levels of Early Lake Ontario were far below present day lake levels, this would have also included incision into the surfaces which are now lake bed. Sharpe et al. (1999) suggest that basin-wide readjustment may have been responsible for the common occurrence of the distinctive set of river terraces within some valleys. While this idea seems reasonable, there is some inconsistency when compared to the radiocarbon date suggested by the intermediate terrace at EHV2. Even the oldest age within the dating error indicates that the river did not abandon this terrace at the time Lake Iroquois was drained. In fact, the radiocarbon date suggests it was 1500 to 4000 ¹⁴C BP later. However, it is possible that the response of the river channels upstream from the Lake Iroquois outlet was delayed.

Following a relatively rapid drop in base-level, incision can occur as a wave which migrates upstream (Knighton, 1998). Presumably, a drop in the base-level would cause incision near the outlet, but initially this would not effect local valley and channel slopes upstream. Although the contemporary river profiles do show an increase in slopes upstream of the confluence, terraces can be observed a great distance upstream, and thus this change in profile is likely a product of other basin controls (Fig. 14). Differences between the longitudinal profiles upstream of the confluence are likely controlled by differences in regional scale slopes (i.e. spatial character of regional topography immediately following glacial retreat). The longitudinal slopes of the terraces (Fig. 7) appear to closely follow the contemporary channel slopes. This suggests that differential uplift may not have influenced incision processes or that valley incision occurred over a very short period. It is possible that the rapid lowering of base-level due to drainage of Lake Iroquois had some effect on upstream incision, however, the timing and pattern of incision seem to be more complex.

The rising level of Lake Ontario through the Holocene would have reduced incision rates, particularly at reaches just above the outlet. Relatively little incision has occurred at EHV2 in the last 6000 ¹⁴C BP (Fig. 9). Further, the end of Lake Algonquin roughly 10 500 ¹⁴C BP would have reduced the amount of water received on the south slopes of the Oak Ridges Moraine. Consequently, most of the uncertainty regarding valley evolution lies in the period between 10 500 and 6000 ¹⁴C BP. If incision was still active during this time, it is unclear what factors were the most important in driving it. If the majority of river incision occurred before the end of Lake Algonquin, this conflicts with the radiocarbon date taken at EHV2. Post-Algonquin incision could perhaps be associated with a warming of the Holocene climate following the Younger Dryas cold period (Yu and Wright, 2001) or with subsequent high lake stages in the Huron basin. During the Holocene, various high stages in the Lake Huron basin have been described and are thought to be associated with water from glacial Lake Agassiz (Teller, 1985; Buhay and Betcher, 1998). In particular, the Mattawa highstands occurred ca. 10 000 and 8000 ¹⁴C BP, and the Nipissing Flood phase occurred ca. 5000 and 4000 ¹⁴C BP (Eschman and Karrow, 1985; Lewis et al., 1994). However, only the Mattawa highstands correlate with the age of the river terrace at EHV2, and evidence suggests that these lake levels did not significantly submerge areas immediately north of the Oak Ridges Moraine, presumably as a consequence of glacial rebound.

In addition to rising levels in the Lake Ontario basin over the middle Holocene, reduced incision may also have been aided by dryer climates. Evidence of this is shown by Yu et al. (1997) using shifts in oxygen isotopes at Crawford Lake just southwest of the Humber River basin. Yu et al. (1997) suggest that evidence at this lake indicates a dryer climate in the region between ca. 5000 and 2000 ¹⁴C BP. Presumably climate following this period has become wetter, which may also be contributing to the slight increases in incision observed within the last 1000 ¹⁴C BP.

Evidence discussed in this study (EHV1 and EHV3) suggests that there has been some reactivation of incision in the Humber River basin within the last one thousand years, and perhaps more recently. It is possible that this idea is supported by the work of Weninger and McAndrews (1989) on aggradation rates in the lower Humber River valley. Using sediment cores from two flood ponds, they found a significant increase in aggradation rates starting about 150 years ago. These rates far surpassed the measured late Holocene aggradation rates attributed to lake-level rise, prior to 150 years ago. These aggradation rates in the lower Humber River valley are generally considered a response to basin sediment supplies due to erosion from agricultural surfaces, but might also be due to increased incision upstream. Increased incision upstream is not surprising given the effects of deforestation and urbanization on decreases in evapotranspiration and infiltration, and increases in runoff.

While increased human settlement may be the driving factor behind recent incision, the effects of changing basin hydrology on local channel incision are relatively heterogeneous. Variations in local valley and channel slopes, valley confinement, and sediment characteristics will cause variations in the geomorphic response. For example, evidence of recent incision suggests more activity at the EHV1 and EHV3 field sites, with less apparent incision throughout the valley near EHV2.

In summary, observations of valley geometry, river terrace age, and patterns of incision in the Humber River basin, with respect to deglacial events and the early Holocene, indicate that initial incision was rapid and associated with proglacial lake levels and other processes related to both the direct and indirect effects of melt-water. In particular, the high water stages north of the Oak Ridges Moraine and outlet adjustments to the water levels of Lake Iroquois and early Lake Ontario, played a significant role in early valley evolution and river geomorphology. As paleoclimate reconstruction is less definitive, evidence of significant incision in the early Holocene can be attributed to a few possible factors such as an upstream sequence of basin-wide readjustment to a lowered base-level or the further influence of fluctuating lake levels in the Huron basin north of the moraine. While there is still uncertainty regarding incision during the early Holocene, very little incision has occurred during the late Holocene, with the exception of the recent channel incision associated with increased human settlement.