Formation of the Great Lakes (original) (raw)
There is very little dispute today about whether or not the area surrounding the Great Lakes of North America was indeed glaciated. Current discussions tend to center around the features found in the area, the drainage patterns of the region before the Wisconsin Glaciation, and the stages that combined to form the current lakes system.
The modern drainage pattern for the region includes a watershed that encompasses both peninsulas of Michigan, western Wisconsin and Minnesota and the extreme northern portions of Indiana, Ohio as well as the New York panhandle and Southern Ontario. All rivers and streams in these areas drain into the Great Lakes. From the lakes they flow through the St. Lawrence River and into the Atlantic Ocean.
The water from Lakes Superior and Michigan both flow into Lake Huron through the St. Mary's River (Superior) and the Straight of Mackinaw (Michigan). This water in turn flows into Lake Erie through the St. Claire and Detroit rivers. This also includes the water from the Georgian Bay. Lake Erie drains through the Niagara River into Lake Ontario and then out into the Atlantic Ocean through the St. Lawrence River.
Before the advance of the Wisconsin glacier, the flow of water from the region followed much the same course as it does today. The major difference between the two is in the connection between Lakes Huron and Erie and the St. Clair and Detroit Rivers. Before the ice advance, the water from the current Superior, Michigan and Huron basins flowed into the area now occupied by the Georgian Bay off Lake Huron. All of the water from the current Lake Huron area, south to Lake St. Clair, flowed into this waterway. From there it flowed through the area now occupied by the Trent River to the Bay of Quinte on Lake Ontario (Farrand, 1988).
The southeast portion of Michigan and Northern Ohio and Indiana were drianed by the preglacial Erigan River that flowed over the land currently occupied by Lake Erie, over the Niagara Escarpment and through the area of Lake Ontario where it merged with the water from the upper portion of the basin and then out to sea through the ancestral St. Lawrence basin (Farrand, 1988).
As the lobes shrank back into the valleys that directed their flow, the increased meltwater, combined with the damming of that water by the Valporaiso-Fort Wyane moraines helped to form the first two ancestral Great Lakes, Early Lake Chicago and Early Lake Maumee. Lake Chicago formed in the basin of the Michigan Lobe while Lake Maumee pooled in the Erie basin (Farrand, 1988).
The first stage of Lake Maumee, called Highest Maumee, rose to a level of about 250 meters above sea level. At this point the water found an outlet through the Fort Wayne Moraine and flowed out through the Wabash River valley and then to the Mississippi River. While the water was at this high point, it built beaches along its southern shore. These sand beach ridges still exist today, and were the foundation for many early American trails through the wetlands of the area, and later modern higways (Hansen, 1999).
Later stages of Lake Maumee (Lowest and Middle) had a lower water level because the northward retreating ice had exposed two lower outlet channels. The Lowest Maumee drained through the Grand River and into Lake Chicago. The Middle Maumee was unable to drain through the Grand River directly, as readvancing ice had blocked that passage. However, there was another channel through what is called the Imlay Outlet. This outlet also flowed westward through Michigan, but did not connect direclty to Lake Chicago, but merged with the Grand River west of Lake Maumee (Hansen, 1999).
Many advances and retreats of the glacier formed several lake stages, the highest of which was Lake Whittlesey (225 m) which drained indirectly through central Michigan and the Grand River. The most recent stage has been identified as Lake Lundy. Some evidence suggests that Lake Lundy may have drained eastward through the Mohawk Valley in New York. With the further retreat of the ice sheet, a new channel was opened over the Niagara Excarpment. This large release of water formed Lake Iroquois in the Ontario Basin. From there the water flowed out to sea through the Mohawk Valley (Farrand, 1988).
The quick outflow of this water caused the level of the lake to drop 46 meters, which would have practically drained the lake except for the deeper parts of the western Erie Basin. The isostatic rebound of the bedrock caused by the removal of the ice sheet slowly alowed water to accumulate in the entire Erie Basin by raising the elevation of the Niagara Escarpment (Hansen, 1999).
Reprinted with permission, US Army Corps of Engineers
The Upper Great Lakes
The Upper Great Lakes (Michigan, Huron and Superior) went through similar stages of high a low water levels, coinciding with the advance and retreat of the major ice lobes in each basin. Lake Chicago was nearly forced from its banks with the Lake Border advance about 500 years after the lake was formed.
The Port Huron advance ended about 13,000 b.p. with three major lakes in existence, the Chicago, the Saginaw in the Huron basin, and the Wittlesey in the Erie basin. Each of these three lake drained through the Chicago-Illinois river valley. The Wittlesey drained through the Ubly channel into the Saginaw and the Saginaw drained through the Grand River into Lake Chicago. Lake Wittlesey and Lake Saginaw are actually believed to be parts of one lake, Lake Arkona, but seperated by an advance of the Huron Lobe (Farrand, 1988). Lake Saginaw was a shallow, but widespred lake that was about 80 kilometers inland and 35 meters above present Lake Huron.
After the Port Huron advance, the ice retreated above the Straits of Mackinac and exposed a lower outlet at Kirkfield, Ontario. This outlet lead into the Trent Valley from the Georgian Bay and into Lake Ontario. With this new, lower outlet, the waters of both Lake Michigan and Lake Huron were diverted from the Chicago outlet and into the Atlantic Ocean (Farrand, 1988). During this same interval the earliest lake formed in the Superior basin, Lake Keweenaw. This lake occupied about two-thirds of the basin.
One last major advance in the Upper Great Lakes sector again divided Lake Huron and Lake Michigan. Afterward the ice began its final retreat that eventually would see it leave the continent. This retreat allowed for the formation of Lake Algonquin, which was a merging of the waters of the Michigan and Huron basins with those in the Superior Basin. This lake was drained by both the Chicago outlet and through the St. Clair River into the newly established lakes Erie and Ontario.
As the ice continued to retreat, progressively lower outlets were revealed across Ontario through the North Bay and the Ottawa River. These lower and lower outlets caused the water level in Lake Stanley (in the Huron Basin) to fall. This in turn caused water in Lake Chippewa (in the Michigan Basin) to flow through the Mackinac River.
With the weight of the overburdening ice sheet removed, the process of isostatic rebound began. Rising by about 30 cm per century (Leelanau, 2004), the crust underlying the North Bay began to rise. This caused the water levels in the upper basin to rise as well, forming the Lake Nipissing Great Lakes, which occupied the Michigan, Huron and Superior basins. This rebound is still taking place today, with a rebound of 53 cm per centrury occuring in the Northern Superior Basin.
The rate of crustal reboud differs in different parts of the region. The areas rising fastest are those that had a heavier ice load, and also the areas that were covered in ice most recently. Because the lower basin crust were rebounding more slowly, the northern outlets eventually rose above the level of those to the south. This caused the closure of the North Bay outlet and a reopening of abandoned outlets through the Illinois River and through the St. Clair river into Lake Erie.
When the North Bay outlet was abandoned, the entire water discharge from the upper basins bagan to flow through the Illinois River and the St. Clair River. The Illinois River in the area of Chicago is underlain by limestone, which risisted downcutting. The channel of the St. Clair River is situated in unconsolidated till. As the water form Lake Algonquin flowed through, the elevation of the St. Clair River steadily declined. Eventually, the level fell below that of the Illinois River. The western outlet was abandoned and the entire discharge of Lakes Superior, Michigan and Huron began flowing through the St. Clair exclusively (Farrand, 1988).
With the redirecting of the Upper Basin flow through the St. Clair River at Port Huron, the configuration fo the Great Lakes reached a stage that they essentially hold today. There have been some shifting in shorlines and lake levels, but the hydrologic flow has been consinstent since the abandonment of the North Bay and the Illinois outlets.
| Major Stages of in Evolution of Great Lakes | |||||
|---|---|---|---|---|---|
| Years Ago | Deployment of Ice Sheet Front | Lake Basin | Lake Stage | Altitude | Outlet |
| 14,500? | Retreat and halt at Valporaiso, Charlotte and Ft. Wayne moraines | Michigan | Early Chicago | 195? | Chicago |
| Erie | Highest Maumee | 244 | Ft. Wayne | ||
| Retreating | Michigan | Chicago (Glenwood) | 195 | Chicago | |
| Huron | Early Saginaw | 223 | Grand River | ||
| Erie | Lowest Maumee | 232 | North of Imlay | ||
| 14,000 | Minor advance and halt at Lake Border Moraines | Michigan | Chicago (Glenwood) | 195 | Chicago |
| Erie | Middle Maumee | 238 | Imlay & Ft. Wayne | ||
| 13,000 to 12,000 | Advance and halt at Pt. Huron moraine | Michigan | Chicago (Glenwood) | 195 | Chicago |
| Huron | Saginaw | 212 | Grand River | ||
| Erie | Wittlesey | 226 | Ubly | ||
| 12,000 | Retreating Growth of Two Creeks forest | Superior | Keweenaw | ? | St. Croix River |
| Michigan, Huron | Twocreekan low level | below 177 | Kirkfeld & others? | ||
| Erie | Low level | mostly dry | Niagara | ||
| 11,800 | Advance and halt at Two Rivers moraine and equivalents | Superior | Filled with ice | ||
| Michigan | Chicago (Calumet) | 189/184 | Chicago | ||
| Huron | Algonquin | 184 | St. Clair River | ||
| Erie | Early Erie | below present | Niagara | ||
| 11,000 | Retreating (Kirkfeld outlet still closed) | Superior | Early Duluth | 330 | St. Croix River & Moose Lake |
| Michigan, Huron | Algonquin | 184 | St. Clair River & Chicago | ||
| Erie | Early Erie | bleow present | Niagara | ||
| 10,000 to 9,800 | Marquette advance in Superior basin | Superior | Mostly ice filled, Minong in east | St. Mary's River | |
| Michigan | Chippewa | 70 | Mackinac River | ||
| Huron | Stanley, Hough | 56 | North Bay | ||
| Erie | Rising | Niagara | |||
| 9,500 to 8,000 | Final retreat into Hudson Bay upland | Superior | Main Minong, then falling to Houghton | St. Mary's River | |
| Michigan | Rising from Chippewa | Mackinac River | |||
| Huron | Rising from Stanley | North Bay | |||
| Erir | Rising | below present | Niagara | ||
| 6,000 to 4,000 | No ice sheet on the North American mainland | Superior, Michigan, & Huron | Nipissing Great Lakes | 184 | North Bay, St. Clair River & Chicago |
| Erie | Near to present configuration | 168 | Niagara | ||
| 3,500 to 2,000 | Superior, Michigan & Huron | Level fluctuating climatically, incl. Algoma | St. Clair River & Chicago | ||
| Erie | Essentially modern | Niagara | |||
| 2,000 to present | Superior | Mondern | 183 | St. Mary's River | |
| Michigan, Huron | Modern | 176 | St. Clair River | ||
| Erie | Modern | 174 | Niagara |
Adapted from Farrand, 1988