Investigation of creep instability as a mechanism for glacier surges

Creep instability, the runaway increase of internal temperature and deformation rate, has been suggested as a possible cause of surges of cold glaciers. We investigate this by considering a simple slab model which includes the effect of ice advection normal to the surface. Whether a steady-state sol...

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Bibliographic Details
Main Authors: Paterson, W.S.B., Nitsan, U., Clarke, G.K.C.
Language:unknown
Published: 2011
Subjects:
58 GEOSCIENCES
GLACIERS
CREEP
ACTIVATION ENERGY
ADVECTION
ARRHENIUS EQUATION
GEOTHERMAL ENERGY
HEAT FLOW
HEAT TRANSFER
STABILITY
ENERGY
ENERGY SOURCES
ENERGY TRANSFER
MASS TRANSFER
MECHANICAL PROPERTIES
RENEWABLE ENERGY SOURCES
Antarctic
The Antarctic
Antarc*
Ice Sheet
Online Access:http://www.osti.gov/servlets/purl/7212776
https://www.osti.gov/biblio/7212776
Description
Summary:Creep instability, the runaway increase of internal temperature and deformation rate, has been suggested as a possible cause of surges of cold glaciers. We investigate this by considering a simple slab model which includes the effect of ice advection normal to the surface. Whether a steady-state solution of the heat transfer equation exists depends on the value of a ''stability parameter'' proportional to the ratio of the rate of deformational heat production to the rate at which this heat is conducted away. If the parameter exceeds a certain critical value, instability occurs and basal ice eventually reaches melting point. The ice mass can then start to slide over its bed. If the stability parameter exceeds a second higher critical value, a layer of basal ice at melting point will form. The critical values depend on geothermal heat flux and strongly on advection. Upward advection, as in the ablation area, decreases stability whereas downward advection (accumulation) increases it. On the other hand, if unstable conditions exist, accumulation increases the growth rate of the instability while ablation decreases it. Calculations suggest that certain natural ice masses may be unstable. The time for the instability to develop, however, is of the order of 100 to 10,000 yr., whereas the residence time of the ice in many glaciers is less than 10,000 yr. Moreover, observed periodicities of glacier surges are between 10 and 100 yr. It thus appears that creep instability cannot explain glacier surges. These arguments do not, however, eliminate the possibility of creep instability causing surges in the Antarctic ice sheet or in large ice-age ice sheets with low accumulation rates.

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