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Autori principali: Holden, Sidney, Morrell, Mia C., Vasil, Geoffrey, Katifori, Eleni
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2605.16130
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author Holden, Sidney
Morrell, Mia C.
Vasil, Geoffrey
Katifori, Eleni
author_facet Holden, Sidney
Morrell, Mia C.
Vasil, Geoffrey
Katifori, Eleni
contents Adaptive transport networks in biological and physical systems exhibit hierarchical organization, characteristic channel spacing, and robust scaling relations. Existing adaptive network models, formulated on a lattice, successfully reproduce many observed topologies and conduit scaling laws; however, the mechanism that selects network density and spatial spacing remains unclear. We address this in a continuum formulation where conductivity evolves as a tensor field coupled to pressure-driven flow. Linearizing about a homogeneous conducting state, we identify a finite-wavelength instability with a $-1/4$ preferred wavelength scaling in the control parameter. Simulations of the full equations confirm the analytical predictions and demonstrate the formation of anisotropic conducting structures above threshold. These results establish a scale-selection principle for adaptive transport network formation which arises from a pattern-forming instability rather than solely from relaxation within a nonconvex energy landscape. The instability mechanism places adaptive transport systems within a broader class of nonequilibrium pattern-forming media in which constitutive transport feedback generates spatial organization. Beyond reproducing hierarchical scaling laws, the theory additionally predicts the intrinsic density of transport networks and the spatial scale of resource delivery.
format Preprint
id arxiv_https___arxiv_org_abs_2605_16130
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Length-scale selection in adaptive transport networks
Holden, Sidney
Morrell, Mia C.
Vasil, Geoffrey
Katifori, Eleni
Adaptation and Self-Organizing Systems
Adaptive transport networks in biological and physical systems exhibit hierarchical organization, characteristic channel spacing, and robust scaling relations. Existing adaptive network models, formulated on a lattice, successfully reproduce many observed topologies and conduit scaling laws; however, the mechanism that selects network density and spatial spacing remains unclear. We address this in a continuum formulation where conductivity evolves as a tensor field coupled to pressure-driven flow. Linearizing about a homogeneous conducting state, we identify a finite-wavelength instability with a $-1/4$ preferred wavelength scaling in the control parameter. Simulations of the full equations confirm the analytical predictions and demonstrate the formation of anisotropic conducting structures above threshold. These results establish a scale-selection principle for adaptive transport network formation which arises from a pattern-forming instability rather than solely from relaxation within a nonconvex energy landscape. The instability mechanism places adaptive transport systems within a broader class of nonequilibrium pattern-forming media in which constitutive transport feedback generates spatial organization. Beyond reproducing hierarchical scaling laws, the theory additionally predicts the intrinsic density of transport networks and the spatial scale of resource delivery.
title Length-scale selection in adaptive transport networks
topic Adaptation and Self-Organizing Systems
url https://arxiv.org/abs/2605.16130