1972
DOI: 10.1029/wr008i006p01506
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Stability and the conservation of mass in drainage basin evolution

Abstract: Drainage basin evolution is modeled as the time development of an initial surface subject to conservation of sediment and water and a transport law qs = F(S, q) connecting the sediment flux qs with the local slope S and the discharge of surface water q. Two models are presented. The first is appropriate to a smooth surface on which no discrete channels have formed, and the second is appropriate to a family of V‐shaped valleys, each containing a separate stream of negligible width. For the first model, some sol… Show more

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Cited by 349 publications
(359 citation statements)
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“…The basic mechanism here is that regions of high plume velocity induce enhanced heat transfer and thus faster melting, which increases the local transverse slope of the ice-shelf and leads to flow focussing. There is a partial analogy with hill-slope erosion (Smith & Bretherton 1972). We seek to determine how a one-dimensional ice-shelf profile is affected by transverse perturbations in the conditions at the grounding line.…”
Section: Introductionmentioning
confidence: 99%
“…The basic mechanism here is that regions of high plume velocity induce enhanced heat transfer and thus faster melting, which increases the local transverse slope of the ice-shelf and leads to flow focussing. There is a partial analogy with hill-slope erosion (Smith & Bretherton 1972). We seek to determine how a one-dimensional ice-shelf profile is affected by transverse perturbations in the conditions at the grounding line.…”
Section: Introductionmentioning
confidence: 99%
“…This positive feedback induces instability, as was shown by SMITH and BRETHERTON (1972), in their pioneering study.…”
Section: Introductionmentioning
confidence: 89%
“…We complete the previous modeling of the problems by SMITH and BRETHERTON (1972) and FOWLER et al (2007), obtaining a model which involves a degenerate nonlinear parabolic equation (satisfied on the interior of the support of the solution) with a superlinear source term and a prescribed constant mass. We propose here a global formulation of the problem (formulated in the whole space, beyond the support of the solution) which allows us to show the existence of a solution and leads to a suitable numerical scheme for its approximation.…”
Section: Discussionmentioning
confidence: 99%
“…The second group has produced remarkable simulations of evolving channel networks; see [52,53], [18], [48] and [35]. The third group has lead to an increasing understanding of the physical mechanisms that underlie erosion and channel formation; see [40], [42], [30], [36], [28], [27], [29], [43], [22,23,24,25,21], [44,45,46], [39], [50], [9], [15], [7], [41].…”
Section: Introductionmentioning
confidence: 99%
“…These equations improve the original model in [42] by including a pressure term (in addition to the gravitational and friction terms) that prevents water from accumulating in an unbounded manner in surface concavities; see [28]. They present a representation of the free water surface in a diffusion analogy approximation to the St. Venant equations; see [51].…”
Section: Introductionmentioning
confidence: 99%