Asymptotic strain-gradient theory for one-dimensional continua

Manon Thbaut; Basile Audoly; Claire Lestringant

doi:10.1016/j.jmps.2025.106392

Asymptotic strain-gradient theory for one-dimensional continua

Manon Thbaut
, Basile Audoly
, Claire Lestringant

Department of Mechanics École Polytechnique
Institut Jean Le Rond d'Alembert

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

Abstract

The goal of periodic homogenization is to identify an effective model specified by an energy functional Φ_ɛ[u] depending on the macroscopic displacement u. We consider second-order homogenization, a case where the effective energy depends not only on the strain u^′ but also on its gradients u^′′ and u^′′′. Functionals Φ_ɛ[u] obtained in prior work are typically made stationary order by order in the expansion parameter, and are not positive when truncated: they are not proper strain-gradient theories. Starting from a functional Φ_ɛ[u] produced by linear, second-order homogenization of a periodic elastic lattice in dimension 1, we propose a systematic method to upgrade it to a positive strain-gradient energy Ψ_ɛ[u]. This enables us to formulate second-order homogenization as a variational problem. Boundary layers are represented in an effective and asymptotically correct way by boundary terms in the energy Ψ_ɛ[u].

Original language	English
Article number	106392
Journal	Journal of the Mechanics and Physics of Solids
Volume	206
DOIs	https://doi.org/10.1016/j.jmps.2025.106392
Publication status	Published - 1 Jan 2026
Externally published	Yes

Keywords

Higher-order homogenization
Strain-gradient elasticity
Variational methods

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10.1016/j.jmps.2025.106392

Cite this

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title = "Asymptotic strain-gradient theory for one-dimensional continua",

abstract = "The goal of periodic homogenization is to identify an effective model specified by an energy functional Φɛ[u] depending on the macroscopic displacement u. We consider second-order homogenization, a case where the effective energy depends not only on the strain u′ but also on its gradients u′′ and u′′′. Functionals Φɛ[u] obtained in prior work are typically made stationary order by order in the expansion parameter, and are not positive when truncated: they are not proper strain-gradient theories. Starting from a functional Φɛ[u] produced by linear, second-order homogenization of a periodic elastic lattice in dimension 1, we propose a systematic method to upgrade it to a positive strain-gradient energy Ψɛ[u]. This enables us to formulate second-order homogenization as a variational problem. Boundary layers are represented in an effective and asymptotically correct way by boundary terms in the energy Ψɛ[u].",

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T1 - Asymptotic strain-gradient theory for one-dimensional continua

AU - Thbaut, Manon

AU - Audoly, Basile

AU - Lestringant, Claire

PY - 2026/1/1

Y1 - 2026/1/1

N2 - The goal of periodic homogenization is to identify an effective model specified by an energy functional Φɛ[u] depending on the macroscopic displacement u. We consider second-order homogenization, a case where the effective energy depends not only on the strain u′ but also on its gradients u′′ and u′′′. Functionals Φɛ[u] obtained in prior work are typically made stationary order by order in the expansion parameter, and are not positive when truncated: they are not proper strain-gradient theories. Starting from a functional Φɛ[u] produced by linear, second-order homogenization of a periodic elastic lattice in dimension 1, we propose a systematic method to upgrade it to a positive strain-gradient energy Ψɛ[u]. This enables us to formulate second-order homogenization as a variational problem. Boundary layers are represented in an effective and asymptotically correct way by boundary terms in the energy Ψɛ[u].

AB - The goal of periodic homogenization is to identify an effective model specified by an energy functional Φɛ[u] depending on the macroscopic displacement u. We consider second-order homogenization, a case where the effective energy depends not only on the strain u′ but also on its gradients u′′ and u′′′. Functionals Φɛ[u] obtained in prior work are typically made stationary order by order in the expansion parameter, and are not positive when truncated: they are not proper strain-gradient theories. Starting from a functional Φɛ[u] produced by linear, second-order homogenization of a periodic elastic lattice in dimension 1, we propose a systematic method to upgrade it to a positive strain-gradient energy Ψɛ[u]. This enables us to formulate second-order homogenization as a variational problem. Boundary layers are represented in an effective and asymptotically correct way by boundary terms in the energy Ψɛ[u].

KW - Higher-order homogenization

KW - Strain-gradient elasticity

KW - Variational methods

UR - https://www.scopus.com/pages/publications/105020260073

U2 - 10.1016/j.jmps.2025.106392

DO - 10.1016/j.jmps.2025.106392

M3 - Article

AN - SCOPUS:105020260073

SN - 0022-5096

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JO - Journal of the Mechanics and Physics of Solids

JF - Journal of the Mechanics and Physics of Solids

M1 - 106392

ER -

Asymptotic strain-gradient theory for one-dimensional continua

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Keywords

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