What question did this study set out to answer?

The research aims to develop a multiscale method for calculating the effective elastic properties of composite materials with fibrous fillers.

February 5, 2026Open Access

Homogenization of Polymer Composite Materials Using Discrete Element Modeling

Key Points

The research aims to develop a multiscale method for calculating the effective elastic properties of composite materials with fibrous fillers.
Used a unified algorithmic scheme for multiscale modeling.
Employed molecular dynamics for atomic level elastic constant calculations.
Applied discrete element method for mesoscale elastic property assessment.
Tested the method on symmetrical fiber placement configurations.
Demonstrated effective elastic properties calculation through multiscale models.
Validated method against problems with known analytical solutions.
Addressed complex issues like fiber cracking and matrix–fiber debonding in defect composites.

Abstract

A multiscale approach to calculating the effective elastic properties of a composite material with a fibrous filler and a polymer matrix is presented. Modeling at various scales is performed using a unified algorithmic scheme, solving Cauchy problems for systems of ordinary differential equations. At the atomic level, molecular dynamics modeling is used to calculate the elastic constant tensor of the polymer material. At the mesoscale, the author’s discrete element method is applied to calculate the effective elastic properties of the composite material. The method was tested on problems with regular fiber placement with symmetry, which have an analytical solution. The capabilities of the proposed approach are demonstrated using defect composite homogenization problems, where symmetry is broken. Fiber cracking and matrix–fiber debonding are considered.

Homogenization of Polymer Composite Materials Using Discrete Element Modeling

Key Points

Abstract

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