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Autori principali: Liu, Yankang, Zhang, Ke, Raissi, Maziar, Zandi, Roya
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.12170
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author Liu, Yankang
Zhang, Ke
Raissi, Maziar
Zandi, Roya
author_facet Liu, Yankang
Zhang, Ke
Raissi, Maziar
Zandi, Roya
contents We learn parameterized nonlinear elasticity on curved surfaces using a physics-informed neural network that enforces governing equations and boundary conditions directly through the loss function, enabling a single trained model to represent a continuous family of elastic equilibria across geometric and material parameters. Nonlinear elasticity on curved manifolds underlies the mechanics of crystalline shells, elastic membranes, and viral capsids, where curvature and topological defects determine equilibrium structure and stability. Traditional exact and finite element solvers rely on symmetry reduction and must be reinitialized for each parameter choice, limiting scalability when symmetry is broken or parameters vary. We validate the proposed learning-based solver on a benchmark problem from curved elasticity, namely the one-dimensional single disclination on a spheroidal surface with known exact and numerical solutions. The network accurately reproduces these solutions, including parameter combinations excluded from training, demonstrating generalization across geometry and material regimes. This study establishes a scalable framework for learning nonlinear elastic systems on curved manifolds and lays the groundwork for extensions to fully two-dimensional and multi-defect configurations relevant to protein shells and other curved elastic networks.
format Preprint
id arxiv_https___arxiv_org_abs_2604_12170
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning Parameterized Nonlinear Elasticity on Curved Surfaces
Liu, Yankang
Zhang, Ke
Raissi, Maziar
Zandi, Roya
Biological Physics
Computational Engineering, Finance, and Science
We learn parameterized nonlinear elasticity on curved surfaces using a physics-informed neural network that enforces governing equations and boundary conditions directly through the loss function, enabling a single trained model to represent a continuous family of elastic equilibria across geometric and material parameters. Nonlinear elasticity on curved manifolds underlies the mechanics of crystalline shells, elastic membranes, and viral capsids, where curvature and topological defects determine equilibrium structure and stability. Traditional exact and finite element solvers rely on symmetry reduction and must be reinitialized for each parameter choice, limiting scalability when symmetry is broken or parameters vary. We validate the proposed learning-based solver on a benchmark problem from curved elasticity, namely the one-dimensional single disclination on a spheroidal surface with known exact and numerical solutions. The network accurately reproduces these solutions, including parameter combinations excluded from training, demonstrating generalization across geometry and material regimes. This study establishes a scalable framework for learning nonlinear elastic systems on curved manifolds and lays the groundwork for extensions to fully two-dimensional and multi-defect configurations relevant to protein shells and other curved elastic networks.
title Learning Parameterized Nonlinear Elasticity on Curved Surfaces
topic Biological Physics
Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2604.12170