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Auteurs principaux: Caputo, J. -G., Cruz-Pacheco, G., Gatlik, J., Sarels, B.
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2604.15246
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author Caputo, J. -G.
Cruz-Pacheco, G.
Gatlik, J.
Sarels, B.
author_facet Caputo, J. -G.
Cruz-Pacheco, G.
Gatlik, J.
Sarels, B.
contents We investigate numerically the blocking of two-dimensional bistable reaction diffusion fronts by geometric obstacles. Our goal is to derive quantitative criteria for front propagation in the presence of spatial heterogeneities. Using a conservation law approach, we show that the integral of the reaction term acts as an effective driving force for the front. Combining this insight with the exact one-dimensional traveling wave solution, we construct a reduced analytical model that predicts blocking thresholds. In particular, we obtain explicit conditions for front propagation in a waveguide connected to a conical region of angle theta, valid for widths w less than 4. The model captures the influence of both geometry and nonlinearity, and shows good agreement with numerical simulations. Finally, we extend the analysis to more complex geometries, including checkerboard-like obstacles, and derive simple heuristic rules governing front propagation. ~
format Preprint
id arxiv_https___arxiv_org_abs_2604_15246
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Blocking of 2D bistable reaction-diffusion fronts by obstacles
Caputo, J. -G.
Cruz-Pacheco, G.
Gatlik, J.
Sarels, B.
Mathematical Physics
Biological Physics
We investigate numerically the blocking of two-dimensional bistable reaction diffusion fronts by geometric obstacles. Our goal is to derive quantitative criteria for front propagation in the presence of spatial heterogeneities. Using a conservation law approach, we show that the integral of the reaction term acts as an effective driving force for the front. Combining this insight with the exact one-dimensional traveling wave solution, we construct a reduced analytical model that predicts blocking thresholds. In particular, we obtain explicit conditions for front propagation in a waveguide connected to a conical region of angle theta, valid for widths w less than 4. The model captures the influence of both geometry and nonlinearity, and shows good agreement with numerical simulations. Finally, we extend the analysis to more complex geometries, including checkerboard-like obstacles, and derive simple heuristic rules governing front propagation. ~
title Blocking of 2D bistable reaction-diffusion fronts by obstacles
topic Mathematical Physics
Biological Physics
url https://arxiv.org/abs/2604.15246