Abstract
AbstractIn Part 1, we have considered the dynamics of topographically confined glaciers, which may undergo surge cycles when the bed becomes temperate. In this Part 2, we consider the ice discharge over a flatbed, which would self-organize into alternating stream/ridge pairs of wet/frozen beds. The meltwater drainage, no longer curbed by the bed trough, would counter the conductive cooling to render a minimum bed strength at some intermediate width, toward which the stream would evolve over centennial timescale. At this stationary state, the stream width is roughly twice the geometric mean of the stream height and length, which is commensurate with its observed width. Over a flatbed, streams invariably interact, and we deduce that the neighboring ones would exhibit compensating cycles of maximum velocity and stagnation over the centennial timescale. This deduction is consistent with observed time variation of Ross ice streams B and C (ISB/C), which is thus a manifestation of the natural cycle. Moreover, the model uncovers an overlooked mechanism of the ISC stagnation: as ISB widens following its reactivation, it narrows ISC to augment the loss of the meltwater, leading to its stagnation. This stagnation is preceded by ice thickening hence opposite to the thinning-induced surge termination.
Highlights
In Part 1 (Ou, 2021), we have considered the dynamics of a glacier confined in a topographic trough, which may exhibit cyclic surges when the bed becomes temperate
In addition to the positive feedback discerned above, we offer a complementary rationale based on the non-equilibrium thermodynamics (NT)
The expansion is twofold: first, without the topographic constriction, the stream would entrain the ambient ice, and the accompanying cold advection would freeze the ambient bed, resulting in self-organized stream/ridge pair; second, without the topographic trough curbing the meltwater dispersal, it would counter the conductive cooling to yield a minimum in the basal stress at some intermediate stream width
Summary
In Part 1 (Ou, 2021), we have considered the dynamics of a glacier confined in a topographic trough, which may exhibit cyclic surges when the bed becomes temperate. This contrast in the bed condition is well-observed over the Siple coast (Bentley and others, 1998; Kamb, 2001), which can be the outcome of the self-organization rather than a precondition that differentiates the disparate flow, as suggested by some authors (Blankenship and others, 2001)
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