The Editor,
Journal of Glaciology
Sir,
Reference Warren, Benn, Winchester and HarrisonWarren and others (2001) (hereafter referred to as WBWH) present a simple buoyancy-driven model in an attempt to quantitatively describe calving events for Glaciar Nef, a lacustrine glacier with its terminus in Lago Nef, Chilean Patagonia. The model proposed makes use of basic physical principles, primarily elementary beam theory, to determine the location of maximum tensile stress along the base of the glacier near its terminus. The location of maximum stress is then used to predict where the ice will most likely fail, leading to basal crevassing and, possibly, large iceberg calving from the ice snout. This information is further used to determine a possible calving rate and volume of ice discharged. However, there are inconsistencies between the physical model presented and the numerical results shown. The formulation of the model is valid, but the incorrect numerical results invalidate the conclusions made about the possibility of basal crevassing.
As previously stated, the model formulation presented in the original paper is correct. The inconsistency arises when the graphical results are compared with the mathematical formulation, where a discrepancy of almost an order of magnitude is found. One of the original authors (D.B.) was willing to provide the original work. It was here that an error was discovered in the application of the area moment of inertia of the glacier tongue. (Ice thickness h i = h(x) = h 0 + x tan α in figure 9 of the original paper was incorrectly multiplied by 0. 5, a quantity that is then cubed in computing I and thus σx (Equation (2).)
Briefly, the moment induced on a floating ice tongue whose thickness is less than the flotation height the water can support is given by
where flotation thickness hn and stress σz are given by equations (2) and (3), respectively, and all other variables are defined by figure 9 in the original WBWH paper.
To determine the tensile stress acting on the tongue, Equation (1) is inserted into the expression (Reference Gere and TimoshenkoGere and Timoshenko, 1997)
where c is the (vertical) distance from the neutral axis of the body to some point and I is the area moment of inertia. The maximum of Equation (2) will occur for the greatest value of c, which in this case would be all points on the plane where c = 0.5h(x), or the base of the glacier. (Points along the surface of the glacier will have the same magnitude stress, but it will be compressive. The value of c is always taken as positive.) The formula for the moment of inertia of the system, a geometric property of the body, can be directly taken from Equation (6) in the WBWH paper.
Similar to the results presented in WBWH, but using this corrected formulation, the maximum tensile stress is determined for a range of terminal ice thicknesses and for two distinct values of the surface slope α.
The numerical results of Equation (2) are shown in Figure 1. Upon comparison to the original results presented, we see there is a large difference in the calculated maximum basal stress that can occur. The maximum stresses found in this paper are ∼140 kPa, as compared to the ∼1 MPa claimed in WBWH. By itself this discrepancy may not seem to mean much, but when this model is used to predict basal fracture locations, the model proves insufficient.
Two papers, Reference VaughanVaughan (1993) and Reference Gagnon and GammonGagnon and Gammon (1995), present values for the tensile strength of glacial ice. For the purposes of their paper, WBWH use the results of Reference Gagnon and GammonGagnon and Gammon (1995) to determine where tensile failure is most likely to occur as predicted by this model. The results presented by Gagnon and Gammon determine a tensile strength on the order of 1 MPa. Using this value, onecan see from the plots in Figure 1 that the basal tensile stress never reaches this magnitude. This would indicate that this model is insufficient for describing the failure of ice under the influence of buoyant stress alone. Values for tensile strength given by Vaughan are on the order of 0.1 –0.5 MPa, comparable to the stress maxima in Figure 1, but these data are primarily determined from surface studies where the effects of firn lessen the tensile strength of the ice. They are therefore considered irrelevant in a discussion of buoyant stresses initiating fracture at the base of a glacier, so is ignored.
Acknowledgements
I am grateful to D. Benn for providing me with a copy of the original work, K. S. Krughoff for his helpful insights, and to T. Hughes for his encouragement and support.
14 November 2002