Hostname: page-component-848d4c4894-wzw2p Total loading time: 0 Render date: 2024-05-16T04:09:37.143Z Has data issue: false hasContentIssue false
  • English
  • Français

Sediment Source for Melt-Water Deposits

Published online by Cambridge University Press:  20 January 2017

Fred Pessl Jr  and
Jan E. Frederick
Fred Pessl Jr
Affiliation:
U.S. Geological Survey, Puget Sound Earth Sciences Applications Project, University District Building, Suite 125. 1107 N.E. 45th Street, Seattle, Washington 98105, U.S.A.
Jan E. Frederick
Affiliation:
U.S. Geological Survey, Puget Sound Earth Sciences Applications Project, University District Building, Suite 125. 1107 N.E. 45th Street, Seattle, Washington 98105, U.S.A.
Rights & Permissions [Opens in a new window]

Abstract

A question is posed regarding the source of melt-water sediment. Does stagnant ice, functionally separated from active ice and gradually melting in place, contain enough rock debris to account for the volume of melt-water deposits known to exist in deglaciated areas, or does the volume of these deposits require a sediment source in close association with active ice from which the supply of rock debris is continually replenished?

Differing opinions on this question are implied in two contrasting models for deglaciation in the north-eastern United States. One, involving regional stagnation, assumes a sediment source in stagnant glacier ice; the other, involving stagnation-zone retreat, considers active ice the principal sediment source. This paper presents reported values of debris content in glacier ice and uses these values to calculate theoretical sediment volumes for a small drainage basin (1 300 km2) in northeastern U.S.A.

A typical value for the amount of rock debris in temperate glacier ice is 25% (volume) debris content in a 400 mm-thick basal debrisrich zone. This value gives a calculated sediment volume of 0.13 km3, about 6% of the estimated actual volume of melt-Hater sediment in the test basin. Comparison of calculated theoretical sediment volume with the estimated actual sediment volume in the basin indicates that stagnant ice is an inadequate sediment source, and that active ice, rather than stagnant ice, is probably the principal sediment source for melt-water deposits.

Type
Research Article
Information
Annals of Glaciology , Volume 2 , 1981 , pp. 92 - 96
Copyright
Copyright © International Glaciological Society 1981

Introduction

In recent years there has been an increasing inclination on the part of glaciologists and glacial geologists to exchange ideas. Important productive aspects of such discussions are new perspectives, new analytical approaches, and new questions. The recent Ottawa Conference in 1978 (Journal of Glaciology 1979) was a noteworthy example of this new dialogue, with attention focused on the glacier bed where complex physical and chemical mechanisms operate to determine erosional processes, transport modes, and depositional systems.

In the context of this interdisciplinary focus on glacial processes, we pose a question regarding the source of melt-water sediment: does stagnant ice, functionally separated from active ice and gradually melting in place, contain enough rock debris to account for the volume of melt-water deposits known to exist in deglaciated areas, or does the volume of these deposits require a sediment source in close association with active ice from which the supply of rock debris to melt-water streams is continually replenished?

In most melt-water systems envisioned by glacial geologists the bulk of the sediment is assumed to derive from rock debris that has been carried within or on the glacier. One such model, involving regional stagnation of a continental ice sheet, was proposed by Flint (Reference Flint1929, Reference Flint1930) to explain the disappearance of the last ice sheet from parts of the north-eastern United States. This model required that debris concentration in the ice sheet or beneath it at the moment of stagnation was sufficient to account for the volume of late-Wisconsinan melt-water sediments that occur in some glaciated parts of the northeastern United States. An alternate view of late-glacial history in this region contends that: (1) deglaciation was characterized by the systematic northward retreat of an active ice margin bordered by a narrow stagnant zone (Reference JahnsJahns 1941, Reference CurrierCurrier 1941, Reference Schafer, Hartshorn, Wright and FreySchafer and Hartshorn 1965, Reference Koteff and CoatesKoteff 1974, Reference Koteff and PessKoteff and Pessl, in press); (2) that stagnant ice contains relatively little rock debris; and (3) that active ice, acting as a conveyor belt, is necessary to supply significant volumes of rock debris to melt-water streams (Reference Koteff and CoatesKoteff 1974, Reference Koteff and PessKoteff and Pessl, in press).

An opportunity to examine the question of sediment source for melt-water deposits as one aspect of this controversy is presented by recent work in the Shetucket River basin, Connecticut (Fig. l). Black (Reference Black1977) has argued in favor of regional stagnation as the model for deglaciation of the Shetucket River basin. Part of his discussion is based on his interpretation that the relatively small volume of water-laid glacial sediment within this basin precludes a sediment source in active ice, thereby favoring regional stagnation wherein sediment is derived primarily from in situ wasting of dead ice. This paper focuses on the question of the melt-water sediment sources by presenting data on reported values of debris content in glacier ice and by using the Shetucket River basin in north-eastern U.S.A. as a test area to compare these reported values with the volume of melt-water deposits estimated to occur within the basin.

Fig.l. Map of north-eastern United States of America showing location of Shetucket River basin

Debris content in glacial ice

The location and, to some extent, the size of a glacier influence the relative contributions of supraglacial, englacial, and subglacial debris to the total debris load in a glacier. In an alpine environment where valley glaciers prevail, the steady supply of debris as rock fall from steep valley walls onto the surface of the ice is quite significant and can account for much of the sediment load. This sediment can either be carried on the surface of the glacier, be incorporated into the ice and carried englacially, or be washed away by melt-water streams on and adjacent to the ice. Subglacially-derived debris is relatively less significant in an alpine glacier. Debris derived subglacially in a larger ice sheet, however, is a major part of the total sediment load. As the thickness and areal extent of the ice mass increase, the ratio of surface area receiving debris (from nunataks and abutting valley walls) to the area contributing debris subglacially decreases. In this discussion, we assume a negligible contribution from supraglacial debris and concentrate on that sediment which is derived subglacially.

Debris in the basal zone of a glacier is typically concentrated in bands ranging in thickness from a few centimeters to nearly 1 m. The amount of sediment within the debris-rich bands varies considerably; however, the upper limit for significant debris concentrations most often quoted is between 40 and 55% by volume (Reference BoultonBoulton 1970[a], Reference Boulton 1970[b], Reference Boulton1979, Reference Boulton, Wright and MoseleyBoulton and others 1974, Reference BoultonBoulton and others 1979). These sediment-rich bands are typically separated by bands of relatively clean ice (less than 1% debris by volume (Reference BoultonBoulton 1970[b])) ranging in thickness from a few centimeters to, in extreme cases, a few meters. The debris-rich bands are usually not continuous and have been observed in some glaciers to pinch out within a few meters. Many debris bands seem to be related to protuberances of bedrock into the glacier sole. This effect on debris concentration of streamlining from bedrock promontories has been discussed by Boulton and others (Reference Boulton1979). They report that the presence of hummocks and intervening troughs in the bedrock floor causes debris bands to diverge from the up-glacier flanks of the hummocks and to concentrate in the troughs between hummocks, thus increasing the thickness of the debris-rich zone and the debris concentration in the troughs.

The thermal regime of a glacier affects the distribution and concentration of englacial debris. Traditionally, the thermal regime of a glacier has been classified as polar, subpolar, or temperate, depending upon how the temperature gradient varies throughout the ice sheet. As our understanding of glacier dynamics increases, this classification appears oversimplified, but a relationship does seem to exist between the thermal characteristics of a glacier, the height of the englacial debris above the glacier sole, and the concentration of englacial debris. Glaciers with a temperate thermal regime tend to transport debris almost exclusively within the lowermost meter (Reference BoultonBoulton 1976, Reference BoultonBoulton and others 1979). Colder glaciers (subpolar and polar) tend to carry the debris higher in the glacier, from a few meters to, in rare instances, tens of meters above the base (Reference Gow, Epstein and SheehyGow and others 1979, Reference Herron and LangwayHerron and Langway 1979). In both types, the debris is not continuous throughout the thickness of the debrisrich zone but is interlayered with bands of relatively clean ice. Observations from the Camp Century core, Greenland, where a basal temperature of –13°C (Reference Hansen and LangwayHansen and Langway 1966) suggests a polar regime, indicate 15.7 m of debris-rich basal ice with 0.24% debris by weight (Reference Herron and LangwayHerron and Langway 1979), or approximately 0.1% by volume (Table I). The basal debris-rich zone in active ice of Spitsbergen glaciers is 0.4 m thick, and the maximum percentage of debris within the debris bands is 40% (Reference BoultonBoulton 1970[a]). Unusually thick, debris-rich ice, such as the 30.5 to 61.0 m zone reported in the Barnes Ice Cap (Reference GoldthwaitGoldthwait 1951) and the 3 to 15 m-thick basal zone with 4 to 25% debris by volume in the Matanuska Glacier (Reference LawsonLawson 1979), is restricted to ice-marginal areas. Rarely do these zones extend more than 400 to 500 m inward from the ice margin (Reference GoldthwaitGoldthwait 1951, Reference AndrewsAndrews 1972), and they are not representative of basal-debris concentration throughout the ice mass. Similarly, values of 40% debris concentration in a basal zone 2 m thick and 15 to 90% debris concentration in basal ice 3 to 4 m thick (Reference BoultonBoulton 1970[a]) occur in the terminal zone. For the Barnes Ice Cap specifically, a more typical value for the thickness of debris-rich ice exclusive of the ice-marginal zone is about 300 ronl (Reference GoldthwaitGoldthwait, oral communication 1978). At Byrd station, Antarctica, well inland from the ice margin, basal debris-rich ice is 4.82 m thick with 7% debris by volume (Reference Gow, Epstein and SheehyGow and others 1979).

Table I Basal-Debris Content In Selected Glaciers, Calculated Volumes Of Equivalent Water-Laid Sediment Applied To The Shetucket River Basin, And Per Cent Total Sediment Estimated Within The Basin

Weertman (Reference Weertman1961) and Boulton (Reference Boulton1972[a], Reference Boulton, Price and Sugden1972 [b]) have discussed the effect of variations in the thermal regime present Hithin an ice sheet, and have suggested that glaciers are typically frozen to their beds at the ice margin (a polar characteristic), whereas at some distance toward the glacier interior there is water at the base (a temperate characteristic). Clayton and Moran (Reference Clayton, Moran and Coates1974) have expanded on this idea in their “glacier-process form” model in which the thermal regime of an advancing continental ice sheet is divided into three zones: an outermost pro-glacial permafrost zone; a frozen-bed zone along the ice margin; and a thawed-bed zone in the interior of the ice sheet. During retreat, the frozen-bed zone is diminished or absent, and the thawed-bed zone extends outward toward the margin of the ice sheet, characteristic of a temperate-glacier thermal regime. Sugden (Reference Sugden1978) has simulated the basal thermal regime of the Laurentide ice sheet at maximum steadystate conditions. In this model, three main zones delineate different processes acting at the glacier sale: warm-melting, warm-freezing, and cold-based. At the base of the center of the ice sheet there is a large zone of warm melting. A warm-freezing zone, where the most intensive erosion takes place, occurs outward from the center of the ice sheet, beyond the warm-melting zone. This warm-freezing zone is of variable lateral extent and grades into a broad cold-based zone where no significant deposition or erosion occurs. An outer warm-melting zone, characterized by deposition, occurs along the margin of the ice sheet.

The shetucket basin

The Shetucket River basin occupies a small (1 300 km2) upland area in the north-eastern United States (Fig.l) that was last overridden by the Laurentide ice sheet 20 to 22 ka. Deglaciation of this area occurred approximately 14 to 15 ka. The basin has local topographic relief of 50 to 100 m and maximum topographic relief of 395 m. It is bounded on the east and west by lowlands with major south-flowing streams and to the north by dissected highlands of moderate relief. At the southern basin boundary, the Shetucket River joins the Thames River flowing south to the Atlantic Ocean in Long Island Sound.

To determine the total volume of water-" laid glacial sediment derived from the wasting Laurentide ice sheet in the Shetucket basin, the area within the basin containing stratified drift was divided into 73 sub-basins. The sediment volume of each sub-basin was calculated by summation of a series of truncated cones, each defined by isopach contours showing thickness and distribution of water-saturated stratified drift (Reference Thomas, Bednar, Thomas and WilsonThomas C E and others: 1967: plate B). The volume of each truncated cone was calculated according to the equation:

()

where h is the thickness (contour interval), Al is the area of upper surface, and A2 is the area of lower surface. The bottom section can be regarded as a cone, the volume of which is

()

where h b is the thickness (half-contour interval), and A b is the lowermost isopach contour. The total volume of saturated stratified drift in the 73 sub-basins is 1.3 km3 which agrees with the estimate of Black (Reference Black1977: 1336). However, an additional 0.7 km3 has been added to that total to account for the volume of stratified drift that occurs above the water table. This value is based on an estimated average thickness (3 m) of stratified drift above the water table as determined from 155 test holes in stratified drift within the basin from which data on depth to static water level are available (Reference Thomas, Bednar, Thomas and WilsonThomas M P and others 1967: 20–26), and on an estimated 18% of the total basin area underlain by stratified drift (Reference Thomas, Bednar, Thomas and WilsonThomas C E and others 1967: 53).Total volume of stratified drift in the Shetucket basin is, therefore, 2.0 km3

The water-laid glacial sediments in the Shetucket basin are late-Wisconsinan recessional deposits (Reference BlackBlack 1977) and, as such, were most probably associated with a temperate-glacier thermal regime (Reference Clayton, Moran and CoatesClayton and Moran 1974). The location of the basin also occurs in the outer warm-melting zone of Sugden (Reference Sugden1978: fig. 9). Using typical values for the amount of basal debris in temperate ice, i.e. about 25% debris in 400mm-thick basal debris-rich ice, we calculate that the volume of sediment available from a wasting ice mass occupying the Shetucket basin would be 0.13 km3, or only about 6% of the total volume estimated to have been deposited there.

The inadequacy of debris-rich, stagnant basal ice as the principal source of the Shetucket-basin melt-water sediment is also indicated by data from specific glaciers. Calculations of available sediment volume based on reported values of thickness and debris concentration in debris-rich basal ice and the per cent of total sediment in the basin that is accounted for by these calculations are given in Table I. When extreme values of debris concentrations are used they account for only 22% of the total melt-water sediment present within the basin. In an attempt to consider an extreme case of available sediment from the ice mass, an ice-marginal zone, 2 km wide, was assumed to have been present in the basin. This increased the per cent of the total melt-water sediment accounted for to 34% (Table II). Because these values are significantly less than the volume of sediment estimated to be present in the basin, stagnant ice was probably not the principal sediment source. Furthermore, the estimated sediment volume in the Shetucket basin is probably a minimum value. The estimate does not include debris deposited as melt-out till during ice recession, nor does it account for that portion of fine-grained sediment which doubtless was transported beyond the basin boundary as suspended load. Any such additions to the estimated total sediment volume in the Shetucket basin further weaken the argument for stagnant ice as the source of water-laid glacial sediment.

Table II Basal-Debris Content In Ice-Marginal Zones Of Selected Glaciers And Per Cent Total Sediment Estimated Within Shetucket River Basin

Discussion

We recognize that, in addition to the contribution of rock debris from the basal zone of a continental glacier, suprag1acia1 debris also contributes additional sediment to the melt-water drainage system. However, except for basal debris that becomes supraglacial in the terminal zone (due to upward-directed transport in active ice and to surface melting), the percentage of total sediment originated as supraglacial debris on a continental ice sheet is probably very small. This is especially so for an ice sheet dissipating in a region of low-to-moderate topographic relief such as the Shetucket basin where steep, confining bedrockvalley walls and nunatak-forming promontories are not common. However, additional mechanisms, such as fluvial reworking of older glacial deposits and slope processes near the wasting ice sheet may also contribute sediment to the melt-water system. Goldthwait (personal communication 1980) reports that fluvial reworking of pre-existing glacial sediments is a major contributor of sediment to outwash forming today in front of stagnant ice in at least one basin in Alaska. This process may account for a portion of the late-glacial meltwater sediment in the Shetucket River basin. Whether or not it was a significant sediment source is difficult to ascertain. But the primary sediment source of such reworked material is still likely to have been active ice.

Available data on the amount of debris entrained within an ice sheet are sparse, particularly with regard to processes of meltwater sedimentation, and further research dealing with the volume and distribution of entrained glacial debris is most desirable. Debris distribution and debris concentration within an ice sheet appear to be highly variable. As previously noted, bed roughness probably is an important influence on the distribution and concentration of glacially transported debris (Reference BoultonBoulton 1979, Reference Boulton, Morris, Armstrong and ThomasBoulton and others 1979). In addition, clean ice interlayered with sediment-rich bands and anomalously high debris concentrations in ice-marginal zones, as compared to more regionally representative debris concentrations, further complicate a realistic assessment of the volume of glacially transported sediment available to melt-water drainage systems. However, presently available data, applied to the Shetucket basin, tend to support the interpretation that active ice, rather than stagnant ice, is the principle sediment source for melt-water deposits.

References

Andrews, J T 1972 Englacial debris in glaciers. Journal of Glaciology, 11 61: 155 CrossRefGoogle Scholar
Black, R F 1977 Regional stagnation of ice in northeastern Connecticut: an alternative model of deglaciation of part of New England. Geological Society of America Bulletin 88 9: 13311336 Google Scholar
Boulton, G S 1970[a] On the deposition of subglacial and melt-out tills at the margins of certain Svalbard glaciers. Journal of Glaciology 9(56): 231245.Google Scholar
Boulton, G S 1970[b] On the origin and transport of eng1acial debris in Svalbard glaciers.. Journal of Glaciology 9(56): 213229 Google Scholar
Boulton, G S 1971 Eng1acial debris in glaciers: reply to the comments of Dr J. T. Andrews. Journal of Glaciology 10, (60): 410411 Google Scholar
Boulton, G S 1972[a] Eng1acial debris in glaciers: reply to the comments of Dr J. T. Andrews. Journal of Glaciology 11, (61): 155156 Google Scholar
Boulton, G S 1972[b] The role of thermal regime in glacial sedimentation. Price, R J and Sugden, D E. Polar geomorphology: London, Institute of British Geographers:119 (Institute of British Geographers Special Publication 4):Google Scholar
Boulton, G S 1975 Processes and patterns of subglacial sedimentation: a theoretical approach.Wright, H E, Moseley, F. Ice age~ancient and modern. Liverpool, See1 House Press: 742 Google Scholar
Boulton, G S 1976 A genetic classification of tills and criteria for distinguishing tills of different origin. Geografia 12: 6580 Google Scholar
Boulton, G S 1979 Processes of glacial erosion on different substrata. Journal of Glaciology 23(89): 1538 Google Scholar
Boulton, G S, Dent, D L, Morris, E M 1974 Subglacial shearing and ~rushing and the role of water pressures in tills from south-east Iceland. Geografiska Annaler Ser A 56A, (3–4): 135145 CrossRefGoogle Scholar
Boulton, G S, Morris, E M, Armstrong, A A, Thomas, A 1979 Direct measurement of stress at the base of a glacier. Journal of Glaciology 22(86): 324 Google Scholar
Clayton, L, Moran, S R 1974 glacial process form model. Coates, D R. Glacial geomorphology. Binghamton, NY, State University of New York: 89119 Google Scholar
Currier, L W 1941 Disappearance of the last ice sheet in Massachusetts by stagnation zone retreat. Geological Society of America Bulletin 52 (12 pt 2): 1895 Google Scholar
Engelhardt, H R, Harrison, W D, Kamb, W B 1978 Basal sliding and conditions at the glacier bed as revealed by bore-hole photography. Journal of Glaciology 20(84): 469508 Google Scholar
Flint, R F 1929 The stagnation and dissipation of the last ice sheet. Geographical Review 19(2): 256289 Google Scholar
Flint, R F 1930 The glacial geology of Connecticut. Connecticut State Geological and Natural History Survey Bulletin 47 Google Scholar
Goldthwait, R P 1951 Development of end moraines in east-central Baffin Island. Journal of Geology 59(6): 567577 Google Scholar
Gow, A J, Epstein, S, Sheehy, W 1979 On the origin of stratified debris in ice cores from the bottom of the Antarctic ice sheet. Journal of Glaciology 23(89): 185192 CrossRefGoogle Scholar
Hansen, B L, Langway, C C Jr 1966 Deep core drilling in ice and core analysis at Camp Century, Greenland, 1961-1966. Antarctic Journal of the United States 1(5): 207208 Google Scholar
Herron, S, Langway, C C Jr 1979 The debris-laden ice at the bottom of the Greenland ice sheet. Journal of Glaciology 23(89): 193207 Google Scholar
Jahns, R H 1941 Outwash chronology in northeastern Massachusetts (abstract). Geological Society of America Bulletin 1(5): 207208 Google Scholar
Journal of Glaciology 1979 Symposium on glacier beds: the ice-rock interface. Ottawa, 1519 August 1978 Journal of Glaciology 23(89)CrossRefGoogle Scholar
Koteff, C 1974 The morphologic sequence concept and deglaciation of southern New England. Coates, D R (ed) Glacial geomorphology. Binghamton, NY, State University of New York: 121144 Google Scholar
Koteff, C, Pess, 1 F Jr 1976 In press Systematic ice retreat in New England. U.S. Geological Survey Professional Paper 1179 Google Scholar
Lawson, D E 1979 Sedimentological analysis of the western terminus region of the Matanuska Glacier, Alaska. CRREL Report 79(9):Google Scholar
Schafer, J P, Hartshorn, J H 1965 The Quaternary of New England. Wright, H E Jr and Frey, D G. The Quaternary of the United States. Princeton, NJ, Princeton University Press: 113128 Google Scholar
Sugden, D E 1978 Glacial erosion by the Lauretide ice sheet. Journal of Glaciology 20(83): 367391 Google Scholar
Thomas, C E Jr, Bednar, G A, Thomas, M P, Wilson, W E 1967 Hydrogeologic data for the Shetucket River basin, Connecticut. Connecticut Water Resources Bulletin 12 Google Scholar
Thomas, M P, Bednar, G A, Thomas, C E Jr, Wilson, W E 1967 1974 Water resources inventory of Connecticut.Pt 2. Shetucket River basin. Connecticut Water Resources Bulletin 11 Google Scholar
Weertman, J 1961 Mechanism for the formation of inner moraines found near the edge of cold ice caps and ice sheets. Journal of Glaciology 3(30): 965978 Google Scholar
Wold, B, ∅strem, G 1979 Subglacial constructions and investigations at Bondhusbreen, Norway. Journal of Glaciology 23(89): 363379 Google Scholar
Figure 0

Fig.l. Map of north-eastern United States of America showing location of Shetucket River basin

Figure 1

Table I Basal-Debris Content In Selected Glaciers, Calculated Volumes Of Equivalent Water-Laid Sediment Applied To The Shetucket River Basin, And Per Cent Total Sediment Estimated Within The Basin

Figure 2

Table II Basal-Debris Content In Ice-Marginal Zones Of Selected Glaciers And Per Cent Total Sediment Estimated Within Shetucket River Basin