| Title | Effects of Great Lakes water loading upon glacial isostatic adjustment and lake history |
| Author | Clark, J.A.; Zylstra, D.J.; Befus, K.M. |
| Author Affil | Clark, J.A., Wheaton College, Department of Geology and Environmental Science, Wheaton, IL |
| Source | Journal of Great Lakes Research, 33(3), p.627-641, . Publisher: International Association for Great Lakes Research (IAGLR), Ann Arbor, MI, United States. ISSN: 0380- 1330 |
| Publication Date | 2007 |
| Notes | In English. 44 refs. GeoRef Acc. No: 282530 |
| Index Terms | dams; deformation; glacial geology; ice dams; ice sheets; models; shores; Great Lakes--Lake Superior; bathymetry; Cenozoic; digital terrain models; geographic information systems; Great Lakes; information systems; isostatic rebound; Lake Superior; lake-level changes; landform evolution; Laurentide ice sheet; natural dams; North America; paleolakes; paleorelief; Quaternary; shorelines; upper Quaternary |
| Abstract | Over the last century geological studies of the ancestral Great Lakes have the confirmed that the large surface load of the Laurentide ice sheet deformed the region causing tilting of ancient lake shorelines. Models of this glacial isostatic adjustment mechanism have promoted understanding of this process but have only included ice sheet loads as the source of earth deformation in the region. We describe a method, utilizing a model of glacial isostatic adjustment combined with GIS, that recreates the paleohydrology of the Great Lakes. Predictions include the extent of late glacial, postglacial, and Holocene lakes and their associated outlets and bathymetries. This predicted history of the Great Lakes is similar to that obtained from a century of detailed field studies but our method uses only the present digital elevation model, a prescribed ice sheet chronology, and an assumed earth viscoelastic rheology. Ancient lake bathymetry predictions provide an estimate of water loads associated with each lake. The effect of these lake loads upon vertical deformation of the Great Lakes region is shown to be small, less than 15 m, but not insignificant when compared to approximately 150 m of deformation forced by ice and ocean loads. Maximum lake-induced deformation is centered upon Lake Superior where water depths were greatest. Where topography is low relief, prediction of shoreline locations should include the lake loading effect as well as the ice and ocean loads. |
| Publication Type | journal article |
| Record ID | 62002914 |