Scaling limits for a population model with growth, division and cross-diffusion

Marie Doumic; Sophie Hecht; Marc Hoffmann; Diane Peurichard

doi:10.1142/S0218202525500472

Scaling limits for a population model with growth, division and cross-diffusion

Marie Doumic
, Sophie Hecht
, Marc Hoffmann
, Diane Peurichard

Research output: Contribution to journal › Article › peer-review

Abstract

Originally motivated by the morphogenesis of bacterial microcolonies, the aim of this paper is to explore models through different scales for a spatial population of interacting, growing and dividing particles. We start from a microscopic stochastic model, write the corresponding stochastic differential equation satisfied by the empirical measure, and rigorously derive its mesoscopic (mean-field) limit. Under smoothness and symmetry assumptions for the interaction kernel, we then obtain entropy estimates, which provide us with a localization limit at the macroscopic level. Finally, we perform a thorough numerical study in order to compare the three modeling scales.

Original language	English
Pages (from-to)	2611-2660
Number of pages	50
Journal	Mathematical Models and Methods in Applied Sciences
Volume	35
Issue number	12
DOIs	https://doi.org/10.1142/S0218202525500472
Publication status	Published - 1 Nov 2025

Keywords

Interacting measure-valued processes
aggregation equation
cross-diffusion
deterministic macroscopic approximation
growth-fragmentation equation
localization limit
mathematical biology
nonlocal interactions
systems of particles

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10.1142/S0218202525500472

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title = "Scaling limits for a population model with growth, division and cross-diffusion",

abstract = "Originally motivated by the morphogenesis of bacterial microcolonies, the aim of this paper is to explore models through different scales for a spatial population of interacting, growing and dividing particles. We start from a microscopic stochastic model, write the corresponding stochastic differential equation satisfied by the empirical measure, and rigorously derive its mesoscopic (mean-field) limit. Under smoothness and symmetry assumptions for the interaction kernel, we then obtain entropy estimates, which provide us with a localization limit at the macroscopic level. Finally, we perform a thorough numerical study in order to compare the three modeling scales.",

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AU - Doumic, Marie

AU - Hecht, Sophie

AU - Hoffmann, Marc

AU - Peurichard, Diane

PY - 2025/11/1

Y1 - 2025/11/1

N2 - Originally motivated by the morphogenesis of bacterial microcolonies, the aim of this paper is to explore models through different scales for a spatial population of interacting, growing and dividing particles. We start from a microscopic stochastic model, write the corresponding stochastic differential equation satisfied by the empirical measure, and rigorously derive its mesoscopic (mean-field) limit. Under smoothness and symmetry assumptions for the interaction kernel, we then obtain entropy estimates, which provide us with a localization limit at the macroscopic level. Finally, we perform a thorough numerical study in order to compare the three modeling scales.

AB - Originally motivated by the morphogenesis of bacterial microcolonies, the aim of this paper is to explore models through different scales for a spatial population of interacting, growing and dividing particles. We start from a microscopic stochastic model, write the corresponding stochastic differential equation satisfied by the empirical measure, and rigorously derive its mesoscopic (mean-field) limit. Under smoothness and symmetry assumptions for the interaction kernel, we then obtain entropy estimates, which provide us with a localization limit at the macroscopic level. Finally, we perform a thorough numerical study in order to compare the three modeling scales.

KW - Interacting measure-valued processes

KW - aggregation equation

KW - cross-diffusion

KW - deterministic macroscopic approximation

KW - growth-fragmentation equation

KW - localization limit

KW - mathematical biology

KW - nonlocal interactions

KW - systems of particles

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DO - 10.1142/S0218202525500472

M3 - Article

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VL - 35

SP - 2611

EP - 2660

JO - Mathematical Models and Methods in Applied Sciences

JF - Mathematical Models and Methods in Applied Sciences

IS - 12

ER -

Scaling limits for a population model with growth, division and cross-diffusion

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