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Published September 10, 1991 | Published
Journal Article Open

Rheological Nonlinearity and Flow Instability in the Deforming Bed Mechanism of Ice Stream Motion

Kamb, Barclay

Abstract

Contrary to what has recently been assumed in modeling the proposed deforming bed mechanism for the rapid motion of Antarctic ice streams, the rheology of water saturated till is probably highly nonlinear, according to information from soil mechanics and preliminary experiments on till from the base of Ice Stream B. The equivalent flow law exponent n is probably as high as ∼100, and the nonlinearities of the shear stress and effective pressure dependences are closely linked. The high nonlinearity has important consequences for the deforming bed mechanism. A flow system operating by this mechanism can be unstable as a result of feedback from the generation of basal water by shear heating of basal till. The short-term feedback effect is analyzed for a perturbation in a model ice stream in which the basal meltwater is transported through a distributed system of narrow gap-conduits at the ice-till interface. Although the analysis is approximate and some of the system parameters are poorly known, the results suggest that the deforming bed mechanism is unstable for n > ∼ 20. The apparent lack of such an instability in the currently active ice streams implies that their motion is controlled not by the deforming bed mechanism but by some other as yet unidentified mechanism.

Additional Information

© 1991 American Geophysical Union. Received September 20, 1990; revised March 4, 1991; accepted March 25, 1991. Paper number 91JB00946. The Antarctic field work upon which some of this paper is based was supported by the National Science Foundation (grant DPP-8519083). The experimental work giving the results in Figure 2 was done by Hermann Engelhardt. I thank Ronald F. Scott for access to the facilities of the Caltech Soil Mechanics Library. Charles Bentley made helpful comments on the manuscript. Caltech Division of Geological and Planetary Sciences, Contribution 4914.

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