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Main Authors: Knopf, Patrik, Pešić, Anastasija, Trautwein, Dennis
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.21230
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author Knopf, Patrik
Pešić, Anastasija
Trautwein, Dennis
author_facet Knopf, Patrik
Pešić, Anastasija
Trautwein, Dennis
contents In this work, we study a phase-field model for curvature-driven pattern formation in biomembranes. The model is derived as a gradient flow of an energy functional that approximates the two-phase Canham--Helfrich energy. This leads to a Cahn--Hilliard-type equation with cross diffusion for the relative chemical concentration of one lipid phase, coupled to a fourth-order reaction-diffusion equation describing the height profile of the membrane. We first prove the existence of weak solutions for the case of regular double-well potentials, using a minimizing movement scheme to construct approximate solutions. The analysis is then extended to singular potentials, e.g., the Flory--Huggins potential, by approximating them with a Moreau--Yosida regularization. For both cases, we establish higher regularity, continuous dependence on the initial data, and consequently the uniqueness of weak solutions. Finally, we propose a well-posed finite element discretization of the model and present numerical experiments illustrating the effect of different physical parameters on the resulting membrane patterns. Depending on the parameter regime, we observe purely striped, dotted, or snake-like structures.
format Preprint
id arxiv_https___arxiv_org_abs_2511_21230
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Curvature-driven pattern formation in biomembranes: A gradient flow approach
Knopf, Patrik
Pešić, Anastasija
Trautwein, Dennis
Analysis of PDEs
In this work, we study a phase-field model for curvature-driven pattern formation in biomembranes. The model is derived as a gradient flow of an energy functional that approximates the two-phase Canham--Helfrich energy. This leads to a Cahn--Hilliard-type equation with cross diffusion for the relative chemical concentration of one lipid phase, coupled to a fourth-order reaction-diffusion equation describing the height profile of the membrane. We first prove the existence of weak solutions for the case of regular double-well potentials, using a minimizing movement scheme to construct approximate solutions. The analysis is then extended to singular potentials, e.g., the Flory--Huggins potential, by approximating them with a Moreau--Yosida regularization. For both cases, we establish higher regularity, continuous dependence on the initial data, and consequently the uniqueness of weak solutions. Finally, we propose a well-posed finite element discretization of the model and present numerical experiments illustrating the effect of different physical parameters on the resulting membrane patterns. Depending on the parameter regime, we observe purely striped, dotted, or snake-like structures.
title Curvature-driven pattern formation in biomembranes: A gradient flow approach
topic Analysis of PDEs
url https://arxiv.org/abs/2511.21230