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Asymptotics of a heterogeneous Canham–Helfrich flexoelectric biomembrane

Grigor Nika, Paul Steinmann and Michael Stingl
Vol. 14 (2026), No. 2, 257–283
DOI: 10.2140/memocs.2026.14.257
Abstract

An asymptotic analysis is conducted on a two-dimensional heterogeneous Canham–Helfrich flexoelectric biomembrane with constitutive laws rooted in thermodynamic principles. In the linearized Canham–Helfrich theory, the biomembrane’s elasticity is characterized by a fourth-order energy density. For a Canham–Helfrich lipid bilayer membrane with protein inclusions, periodic homogenization yields four distinct effective coefficients. Numerical simulations illustrate the dependence of these homogenized coefficients on the volume fraction and externally applied electric field. This theoretical & computational approach provides a framework that enhances biomembrane behavior understanding under complex loading and complex microstructures, with promising applications in advanced materials modeling and simulation.

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Keywords
unfolding homogenization, multiphysics coupling, thermodynamics, nonsimple elastic surface, generalized continua
Mathematical Subject Classification
Primary: 74A20, 74K15, 74Q05, 74Q15, 80A17
Milestones
Received: 23 April 2025
Revised: 22 December 2025
Accepted: 2 February 2026
Published: 19 March 2026

Communicated by Francesco dell'Isola
Authors
Grigor Nika
Deptartment of Mathematics & Computer Science
Karlstad University
Karlstad
Sweden
Paul Steinmann
Department of Mechanical Engineering
Friedrich–Alexander Universität Erlangen-Nürnberg
Erlangen
Germany		 Glasgow Computational Engineering Centre
University of Glasgow
Glasgow
United Kingdom
Michael Stingl
Department of Mathematics
Friedrich–Alexander Universität Erlangen-Nürnberg
Erlangen
Germany
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