Laplacian networks: Growth, local symmetry, and shape optimization

Devauchelle, Olivier; Szymczak, Piotr; Cohen, Yehuda; Seybold, Hansjörg; Rothman, Daniel H.

doi:10.1103/physreve.95.033113

Cited by 15 publications

(45 citation statements)

References 55 publications

(173 reference statements)

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“…Preliminary model runs were dominated by many narrow channels that scaled with the segment length chosen in the method, which we deemed unreasonable. This is a common behavior in models controlled by Laplace's equation, where all wavelengths are unstable and grow, sometimes called the “ultraviolet crisis” (Devauchelle et al, ; Pecelerowicz & Szymczak, ). It is also important to note that for a given channel depth as modeled here, channel widths cannot be arbitrarily narrow.…”

Section: Moving Boundary Model For Distributary Channel Network: Mb_dcnmentioning

confidence: 99%

Distributary Channel Networks as Moving Boundaries: Causes and Morphodynamic Effects

Shaw

Mahon

et al. 2019

JGR Earth Surface

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We propose an exploratory model to describe the morphodynamics of distributary channel network growth on river deltas. The interface between deep channels and the shallow, unchannelized delta front deposits is modeled as a moving boundary. Steady flow over the unchannelized delta front is friction dominated and modeled by Laplace's equation. Shear stress along the network boundary produces nonlinear erosion rates at the interface, causing the boundary to move and network elements (channels and branches) to form. The model was run for boundary conditions resembling the Wax Lake Delta in coastal Louisiana, 20 parameterizations of sediment transport, and 3 parameterizations of discharge. In each case, the model produced a complex channel network with channel number, width, bifurcation angle, and channel shape depending on the sediment transport formula. For reasonable sediment transport parameters and gradually increasing water discharge, the model produced network characteristics and progradation rates similar to the Wax Lake Delta. This suggests that the model contains the processes responsible for network growth, despite its abstract formulation. Key Points:• Prograding distributary channel networks of varying morphology can be modeled as a simple moving boundary • Nonlinearities in the sediment transport formula dictate channel width, number of branches, bifurcation angle, and channel shape • Evolution is dictated by network morphology, sediment transport, and water discharge Supporting Information:• Supporting Information S1

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Section: Moving Boundary Model For Distributary Channel Network: Mb_dcnmentioning

confidence: 99%

Distributary Channel Networks as Moving Boundaries: Causes and Morphodynamic Effects

Shaw

Mahon

et al. 2019

JGR Earth Surface

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“…where d 1,2 are coefficients determined by the global numerical solution of the Poisson problem, r and θ are local polar coordinates such that θ = ±π coincides with the finger near its tip at r = 0. The principle of local symmetry requires that the fingers grows in a direction such that d 2 = 0 [3,7]. As noted in [4] while the path selection and growth mechanism of fingers is similar at a local level near finger tips for both harmonic (Laplacian) and Poisson fields, the trajectories will differ since the coefficients in (1) depend on the global field.…”

Section: Background: the Numerical Experiments Of Cohen And Rothmanmentioning

confidence: 99%

“…In the Laplacian case the principle of local symmetry states that the coefficient of δ vanishes in the expansion (8) [3]. Effectively this guarantees that the path taken by the finger is such that it maintains local symmetry in the potential field about the tip and is equivalent to maximising the flux into the tip [4,7]. However in the Poisson case this must be modified owing to the contribution of the term (2) that has been added to ψ needed to satisfy the right hand side of Poisson's equation.…”

Section: Derivation Of Asymptotic Finger Pathsmentioning

confidence: 99%

“…Laplacian growth models have been successful in describing many features of these networks: a prominent example of this being an explanation of the remarkable observation that the angle at which streams bifurcate is close to 2π/5 e.g. [6,7,15]. However, the groundwater flow field φ is more appropriately modelled by Poisson's equation, in non-dimensional form, Δφ = −1 where the constant right-hand side represents a constant source (precipitation).…”

Section: Introductionmentioning

confidence: 99%

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Finger Growth and Selection in a Poisson Field

McDonald

2019

J Stat Phys

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Solutions are found for the growth of infinitesimally thin, two-dimensional fingers governed by Poisson's equation in a long strip. The analytical results determine the asymptotic paths selected by the fingers which compare well with the recent numerical results of Cohen and Rothman (J Stat Phys 167:703-712, 2017) for the case of two and three fingers. The generalisation of the method to an arbitrary number of fingers is presented and further results for four finger evolution given. The relation to the analogous problem of finger growth in a Laplacian field is also discussed.

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“…If streams advance at an angle narrower than 72 • , the streamlines entering the two springs will bend away from each other; if streams advance at an angle wider than 72 • , the streamlines entering the springs will bend towards each other [10,11]. The 72 • confluence therefore can be considered a stable fixed point for stream advance [13]. An illustration of such a confluence and its streamlines is shown in figure 1.…”

Section: (B) Growth Directionmentioning

confidence: 99%

Symmetric rearrangement of groundwater-fed streams

Cohen

Devauchelle

et al. 2017

Proc. R. Soc. A.

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Streams shape landscapes through headward growth and lateral migration. When these streams are primarily fed by groundwater, recent work suggests that their tips advance to maximize the symmetry of the local Laplacian field associated with groundwater flow. We explore the extent to which such forcing is responsible for the lateral migration of streams by studying two features of groundwater-fed streams in Bristol, Florida: their confluence angle near junctions and their curvature. First, we find that, while streams asymptotically form a 72° angle near their tips, they simultaneously exhibit a wide 120° confluence angle within approximately 10 m of their junctions. We show that this wide angle maximizes the symmetry of the groundwater field near the junction. Second, we argue that streams migrate laterally within valleys and present a new spectral analysis method to relate planform curvature to the surrounding groundwater field. Our results suggest that streams migrate laterally in response to fluxes from the surrounding groundwater table, providing evidence of a new mechanism that complements Laplacian growth at their tips.

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Laplacian networks: Growth, local symmetry, and shape optimization

Cited by 15 publications

References 55 publications

Distributary Channel Networks as Moving Boundaries: Causes and Morphodynamic Effects

Distributary Channel Networks as Moving Boundaries: Causes and Morphodynamic Effects

Finger Growth and Selection in a Poisson Field

Symmetric rearrangement of groundwater-fed streams

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