Nanocomposites base polymère, renforcés par des particules rigides

Emmanuelle Chabert; Laurent Chazeau; Catherine Gauthier; Rémy Dendievel; Jean Yves Cavaille

doi:10.1051/meca:2004049

Nanocomposites base polymère, renforcés par des particules rigides

Emmanuelle Chabert
, Laurent Chazeau
, Catherine Gauthier
, Rémy Dendievel
, Jean Yves Cavaille

CNRS UMR 5510
Department of Mechanics École Polytechnique
GPM2-INPG

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Polymer based composite materials, often exhibit specific mechanical behaviors when the size of particulate fillers is in the nanometric range. It seems that this specificity could be related to the fact that in this case, the average distance between the filler surfaces has the same order of magnitude than the characteristic macromolecules dimensions, such as the coil diameter, etc. Above the glass transition temperature Tg, these materials display sometimes a much larger reinforcement effect than for classical composites. This can be related to the existence of networks involving either particle/macromolecules/particle or direct particle/particle interactions. In this brief review, the effect of (i) filler shape factor and volume fraction, and (ii) the processing methods are discussed through several examples, as well as some information about modeling aspects, both under linear and non linear conditions.

Titre traduit de la contribution	Polymeric nanocomposites reinforced by stiff particles
langue originale	Français
Pages (de - à)	489-496
Nombre de pages	8
journal	Mecanique et Industries
Volume	5
Numéro de publication	4
Les DOIs	https://doi.org/10.1051/meca:2004049
état	Publié - 1 janv. 2004
Modification externe	Oui

mots-clés

Fillers
Mechanical properties
Modeling
Nanocomposites
Percolation
Polymers

Accès au document

10.1051/meca:2004049

Contient cette citation

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title = "Nanocomposites base polym{\`e}re, renforc{\'e}s par des particules rigides",

abstract = "Polymer based composite materials, often exhibit specific mechanical behaviors when the size of particulate fillers is in the nanometric range. It seems that this specificity could be related to the fact that in this case, the average distance between the filler surfaces has the same order of magnitude than the characteristic macromolecules dimensions, such as the coil diameter, etc. Above the glass transition temperature Tg, these materials display sometimes a much larger reinforcement effect than for classical composites. This can be related to the existence of networks involving either particle/macromolecules/particle or direct particle/particle interactions. In this brief review, the effect of (i) filler shape factor and volume fraction, and (ii) the processing methods are discussed through several examples, as well as some information about modeling aspects, both under linear and non linear conditions.",

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author = "Emmanuelle Chabert and Laurent Chazeau and Catherine Gauthier and R{\'e}my Dendievel and Cavaille, \{Jean Yves\}",

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AU - Chabert, Emmanuelle

AU - Chazeau, Laurent

AU - Gauthier, Catherine

AU - Dendievel, Rémy

AU - Cavaille, Jean Yves

PY - 2004/1/1

Y1 - 2004/1/1

N2 - Polymer based composite materials, often exhibit specific mechanical behaviors when the size of particulate fillers is in the nanometric range. It seems that this specificity could be related to the fact that in this case, the average distance between the filler surfaces has the same order of magnitude than the characteristic macromolecules dimensions, such as the coil diameter, etc. Above the glass transition temperature Tg, these materials display sometimes a much larger reinforcement effect than for classical composites. This can be related to the existence of networks involving either particle/macromolecules/particle or direct particle/particle interactions. In this brief review, the effect of (i) filler shape factor and volume fraction, and (ii) the processing methods are discussed through several examples, as well as some information about modeling aspects, both under linear and non linear conditions.

AB - Polymer based composite materials, often exhibit specific mechanical behaviors when the size of particulate fillers is in the nanometric range. It seems that this specificity could be related to the fact that in this case, the average distance between the filler surfaces has the same order of magnitude than the characteristic macromolecules dimensions, such as the coil diameter, etc. Above the glass transition temperature Tg, these materials display sometimes a much larger reinforcement effect than for classical composites. This can be related to the existence of networks involving either particle/macromolecules/particle or direct particle/particle interactions. In this brief review, the effect of (i) filler shape factor and volume fraction, and (ii) the processing methods are discussed through several examples, as well as some information about modeling aspects, both under linear and non linear conditions.

KW - Fillers

KW - Mechanical properties

KW - Modeling

KW - Nanocomposites

KW - Percolation

KW - Polymers

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DO - 10.1051/meca:2004049

M3 - Article

AN - SCOPUS:11844249962

SN - 1296-2139

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JO - Mecanique et Industries

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ER -

Nanocomposites base polymère, renforcés par des particules rigides

Résumé

mots-clés

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