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Revisit to three-dimensional percolation theory: Accurate analysis for highly stretchable conductive composite materials.


ABSTRACT: A percolation theory based on variation of conductive filler fraction has been widely used to explain the behavior of conductive composite materials under both small and large deformation conditions. However, it typically fails in properly analyzing the materials under the large deformation since the assumption may not be valid in such a case. Therefore, we proposed a new three-dimensional percolation theory by considering three key factors: nonlinear elasticity, precisely measured strain-dependent Poisson's ratio, and strain-dependent percolation threshold. Digital image correlation (DIC) method was used to determine actual Poisson's ratios at various strain levels, which were used to accurately estimate variation of conductive filler volume fraction under deformation. We also adopted strain-dependent percolation threshold caused by the filler re-location with deformation. When three key factors were considered, electrical performance change was accurately analyzed for composite materials with both isotropic and anisotropic mechanical properties.

SUBMITTER: Kim S 

PROVIDER: S-EPMC5046142 | biostudies-literature | 2016 Oct

REPOSITORIES: biostudies-literature

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Revisit to three-dimensional percolation theory: Accurate analysis for highly stretchable conductive composite materials.

Kim Sangwoo S   Choi Seongdae S   Oh Eunho E   Byun Junghwan J   Kim Hyunjong H   Lee Byeongmoon B   Lee Seunghwan S   Hong Yongtaek Y  

Scientific reports 20161003


A percolation theory based on variation of conductive filler fraction has been widely used to explain the behavior of conductive composite materials under both small and large deformation conditions. However, it typically fails in properly analyzing the materials under the large deformation since the assumption may not be valid in such a case. Therefore, we proposed a new three-dimensional percolation theory by considering three key factors: nonlinear elasticity, precisely measured strain-depend  ...[more]

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