An Unconditionally Energy Stable Gradient Flow for Phase Field Modelling of Structural Topology Optimization in Geometrically Nonlinear Elasticity

Jiajie Li; Hui Yang; Shengfeng Zhu

doi:10.1007/s10915-025-03023-8

An Unconditionally Energy Stable Gradient Flow for Phase Field Modelling of Structural Topology Optimization in Geometrically Nonlinear Elasticity

Jiajie Li, Hui Yang, Shengfeng Zhu

School of Mathematical Sciences

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

Abstract

We consider the topology optimization of geometrically nonlinear elasticity problems using a phase field model. A novel generalized stabilized semi-implicit scheme for the gradient flow is proposed to solve the resulting optimal control problem, thereby overcoming the need for extra adjoint variables and nonlinear constraints. Unconditional energy stability is shown for the Allen-Cahn type of gradient flow scheme in both continuous and discrete spaces. The local averaging and superconvergence patch recovery are applied to enhance the accuracy of the discrete gradient, thus the robustness of the phase field gradient flow for topology optimization in nonlinear elasticity. Numerical experiments show the effectiveness and robustness of the optimization algorithm proposed.

Original language	English
Article number	108
Journal	Journal of Scientific Computing
Volume	104
Issue number	3
DOIs	https://doi.org/10.1007/s10915-025-03023-8
State	Published - Sep 2025

Keywords

Energy stability
Gradient recovery
Nonlinear elasticity
Phase field model
Stabilized gradient flow
Topology optimization

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10.1007/s10915-025-03023-8

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title = "An Unconditionally Energy Stable Gradient Flow for Phase Field Modelling of Structural Topology Optimization in Geometrically Nonlinear Elasticity",

abstract = "We consider the topology optimization of geometrically nonlinear elasticity problems using a phase field model. A novel generalized stabilized semi-implicit scheme for the gradient flow is proposed to solve the resulting optimal control problem, thereby overcoming the need for extra adjoint variables and nonlinear constraints. Unconditional energy stability is shown for the Allen-Cahn type of gradient flow scheme in both continuous and discrete spaces. The local averaging and superconvergence patch recovery are applied to enhance the accuracy of the discrete gradient, thus the robustness of the phase field gradient flow for topology optimization in nonlinear elasticity. Numerical experiments show the effectiveness and robustness of the optimization algorithm proposed.",

keywords = "Energy stability, Gradient recovery, Nonlinear elasticity, Phase field model, Stabilized gradient flow, Topology optimization",

author = "Jiajie Li and Hui Yang and Shengfeng Zhu",

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AU - Li, Jiajie

AU - Yang, Hui

AU - Zhu, Shengfeng

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2025.

PY - 2025/9

Y1 - 2025/9

N2 - We consider the topology optimization of geometrically nonlinear elasticity problems using a phase field model. A novel generalized stabilized semi-implicit scheme for the gradient flow is proposed to solve the resulting optimal control problem, thereby overcoming the need for extra adjoint variables and nonlinear constraints. Unconditional energy stability is shown for the Allen-Cahn type of gradient flow scheme in both continuous and discrete spaces. The local averaging and superconvergence patch recovery are applied to enhance the accuracy of the discrete gradient, thus the robustness of the phase field gradient flow for topology optimization in nonlinear elasticity. Numerical experiments show the effectiveness and robustness of the optimization algorithm proposed.

AB - We consider the topology optimization of geometrically nonlinear elasticity problems using a phase field model. A novel generalized stabilized semi-implicit scheme for the gradient flow is proposed to solve the resulting optimal control problem, thereby overcoming the need for extra adjoint variables and nonlinear constraints. Unconditional energy stability is shown for the Allen-Cahn type of gradient flow scheme in both continuous and discrete spaces. The local averaging and superconvergence patch recovery are applied to enhance the accuracy of the discrete gradient, thus the robustness of the phase field gradient flow for topology optimization in nonlinear elasticity. Numerical experiments show the effectiveness and robustness of the optimization algorithm proposed.

KW - Energy stability

KW - Gradient recovery

KW - Nonlinear elasticity

KW - Phase field model

KW - Stabilized gradient flow

KW - Topology optimization

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DO - 10.1007/s10915-025-03023-8

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SN - 0885-7474

VL - 104

JO - Journal of Scientific Computing

JF - Journal of Scientific Computing

IS - 3

M1 - 108

ER -

An Unconditionally Energy Stable Gradient Flow for Phase Field Modelling of Structural Topology Optimization in Geometrically Nonlinear Elasticity

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Keywords

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