Hostname: page-component-848d4c4894-cjp7w Total loading time: 0 Render date: 2024-07-07T09:00:39.002Z Has data issue: false hasContentIssue false
  • English
  • Français

Late Wisconsin Ice-Surface Profile Calculated from Esker Paths and Types, Katahdin Esker System, Maine

Published online by Cambridge University Press:  20 January 2017

Ronald L. Shreve
Ronald L. Shreve*
Affiliation:
Department of Earth and Space Sciences and Institute of Geophysics and Planetary Physics, University of California, Los Angeles, California 90024
Get access Rights & Permissions [Opens in a new window]

Abstract

Values of the gradient of the former ice surface can be inferred at points along a flow line from deviations of esker paths or transitions in esker type and numerically integrated to give the profile. A profile calculated in this way shows that during formation of the Katahdin esker system about 12,700 yr ago the ice thickness at distances of 10, 20, 50, 100, and 140 km from the terminus, which is about two thirds of the distance to the ice divide, was approximately 200, 300, 600, 750, and 900 m. The terminal reach was computed by assuming an unknown uniform basal drag and matching the profile to its known elevation at the terminus and known gradient 10 km upglacier. Correction for isostatic rebound based on the elevations of contemporaneous deltas and of the marine limit proved unnecessary, because the tilt due to the difference in uplift at the two ends of the profile is only 0.1 m km−1. With other plausible assumptions as to sea levels in the past, elevations of the marine limit, or exact location of the terminus the profile could be as much as roughly 100 m higher. It hits Mount Katahdin about 500 m below its summit, which is at 1600 m, in agreement with the geological evidence farther west. The steepening of the upper part of the profile suggests that the mountain dammed and diverted the ice. Basal drag computed from the profile varies from about 20 kPa (0.2 bar) near the terminus to 30 kPa (0.3 bar) at 100 km to 70 kPa (0.7 bar) at 140 km. The relatively low values away from the influence of Mount Katahdin agree with independent evidence from deep-sea cores of substantial late Wisconsin ice-sheet thinning without comparable areal reduction. The method has potential for application over wide areas that were occupied by the Laurentide and Scandinavian ice sheets.

Type
Original Articles
Information
Quaternary Research , Volume 23 , Issue 1 , January 1985 , pp. 27 - 37
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Allen, C.R. Smith, G.I. 1953 Seismic and gravity investigations on the Malaspina Glacier, Alaska American Geophysical Union Transactions 34 755760 Google Scholar
Andrews, J.T. 1968 Pattern and cause of variability of postglacial uplift and rate of uplift in arctic Canada Journal of Geology 76 404425 Google Scholar
Borns, H.W. Jr. 1973 Late Wisconsinan fluctuation of the Laurentide Ice Sheet in southern and eastern New England Black, R.F. Goldthwait, R.P. Willman, H.B. The Wisconsinan Stage. Geological Society of America Memoir. 136 3745 Google Scholar
Borns, H.W. Jr. 1978 Deglacial events in southeastern Maine Ludman, A. Guidebook for Field Trips in Southeastern Maine and Southwestern New Brunswick, October 7 and 8, 1978, New England Intercollegiate Geological Conference, 70th Annual Meeting Queens College Press Flushing, N.Y 102107 Google Scholar
Borns, H.W. Jr. Hughes, T.J. 1977 The implications of the Pineo Ridge readvance in Maine Géographie Physique et Quaternaire 31 203206 CrossRefGoogle Scholar
Broecker, W.S. 1966 Glacial rebound and the deformation of the shorelines of proglacial lakes Journal of Geophysical Research 71 47774783 Google Scholar
Budd, W.F. Jenssen, D. Radok, U. 1971 Derived Physical Characteristics of the Antarctic Ice Sheet Antarctic Division, Department of Supply Melbourne Australian National Research Expeditions, ANARE Interim Reports, Series A (IV) Glaciology, Public. 120Google Scholar
Bull, C. 1957 Observations in north Greenland relating to theories of the properties of ice Journal of Glaciology 3 6772 Google Scholar
Curray, J.R. 1965 Late Quaternary history, continental shelves of the United States Wright, H.E. Jr. Frey, D.G. The Quaternary of the United States Princeton Univ. Press Princeton, N.J 723736 Google Scholar
Dillon, W.P. Oldale, R.N. 1978 Late Quaternary sea-level curve, reinterpretation based on glaciotectonic influence Geology 6 5660 2.0.CO;2>CrossRefGoogle Scholar
Fastook, J.L. Hughes, T.J. 1980 A numerical model for reconstruction and disintegration of the Late Wisconsin glaciation in the Gulf of Maine Larson, G.J. Stone, B.D. Late Wisconsinan Glaciation of New England Kendall/Hunt Dubuque, Iowa 229242 Google Scholar
Haefeli, R. 1961 Contribution to the movement and the form of ice sheets in the arctic and antarctic Journal of Glaciology 3 11331151 CrossRefGoogle Scholar
Harrison, W. 1958 Marginal zones of vanished glaciers reconstructed from the pre-consolidation-pressure value of overridden silts Journal of Geology 66 7295 CrossRefGoogle Scholar
Mathews, W.H. 1974 Surface profiles of the Laurentide Ice Sheet in its marginal areas Journal of Glaciology 13 3743 Google Scholar
Milliman, J.D. Emery, K.O. 1968 Sea levels during the past 35,000 years Science (Washington, D.C.) 162 11211123 Google Scholar
Nye, J.F. 1952a The mechanics of glacier flow Journal of Glaciology 2 8293 Google Scholar
Nye, J.F. 1952b A method of calculating the thickness of the ice-sheets Nature (London) 169 529530 CrossRefGoogle Scholar
Nye, J.F. 1953 The flow law of ice from measurements in glacier tunnels, laboratory experiments and the Jungfraufirn borehole experiment Proceedings of the Royal Society of London, (Series: A) 219 477489 Google Scholar
Nye, J.F. 1969 The effect of longitudinal stress on the shear stress at the base of an ice sheet Journal of Glaciology 8 207213 Google Scholar
Röthlisberger, H. 1972 Water pressure in intra- and subglacial channels Journal of Glaciology 11 177203 Google Scholar
Ruddiman, W.F. McIntyre, A. 1981 The mode and mechanism of the last deglaciation, oceanic evidence Quaternary Research 16 125134 Google Scholar
Schlichting, H. 1955 Boundary Layer Theory McGraw-Hill New York Google Scholar
Shreve, R.L. 1972 Movement of water in glaciers Journal of Glaciology 11 205214 Google Scholar
Shreve, R.L. 1985 Esker Characteristics in Terms of Glacier Physics Geological Society of America Bulletin 96 in pressGoogle Scholar
Stuiver, M. Borns, H.W. Jr. 1975 Late Quaternary marine invasion in Marine, its chronology and associated crustal movement Geological Society of America Bulletin 86 99104 Google Scholar
Thompson, W.B. 1980 Recession of the late Wisconsinan Ice Sheet in coastal Maine Larson, G.J. Stone, B.D. Late Wisconsinan Glaciation of New England Kendall/Hunt Dubuque, Iowa 211228 Google Scholar
Thorson, R.M. 1980 Ice-sheet glaciation of the Puget lowland, Washington, during the Vashon Stade (late Pleistocene) Quaternary Research 13 303321 CrossRefGoogle Scholar
Weertman, J. 1964 The theory of glacier sliding Journal of Glaciology 5 287303 Google Scholar