A comparison between the failure modes observed in biological and synthetic polymer nanocomposites

F. G. Torres; Ana Cecilia Saavedra

doi:10.1080/25740881.2019.1625397

A comparison between the failure modes observed in biological and synthetic polymer nanocomposites

F. G. Torres, Ana Cecilia Saavedra

Research output: Contribution to journal › Review article › peer-review

7 Scopus citations

Abstract

Synthetic polymer nanocomposites display enhanced toughness and energy absorption with regard to unreinforced polymers. The interaction between the polymeric matrix and the reinforcements triggers failure mechanisms such as fiber fracture, crack deflection, among others. Biological nanocomposites sometimes exhibit higher toughness than synthetic nanocomposites due to their hierarchical organization. This arrangement triggers failure modes such as mineral bridging and delamination. This review summarizes and classifies systematically the failure mechanisms involved in these nanocomposites. These failures modes are compared for a better understanding and to provide new design criteria for the development of novel bioinspired polymer nanocomposites with enhanced mechanical properties.

Original language	English
Pages (from-to)	241-270
Number of pages	30
Journal	Polymer-Plastics Technology and Materials
Volume	59
Issue number	3
DOIs	https://doi.org/10.1080/25740881.2019.1625397
State	Published - 11 Feb 2020

Keywords

Failure mechanism
biological nanocomposites
polymer nanocomposites
synthetic polymeric nanocomposites

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10.1080/25740881.2019.1625397

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abstract = "Synthetic polymer nanocomposites display enhanced toughness and energy absorption with regard to unreinforced polymers. The interaction between the polymeric matrix and the reinforcements triggers failure mechanisms such as fiber fracture, crack deflection, among others. Biological nanocomposites sometimes exhibit higher toughness than synthetic nanocomposites due to their hierarchical organization. This arrangement triggers failure modes such as mineral bridging and delamination. This review summarizes and classifies systematically the failure mechanisms involved in these nanocomposites. These failures modes are compared for a better understanding and to provide new design criteria for the development of novel bioinspired polymer nanocomposites with enhanced mechanical properties.",

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AU - Saavedra, Ana Cecilia

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N2 - Synthetic polymer nanocomposites display enhanced toughness and energy absorption with regard to unreinforced polymers. The interaction between the polymeric matrix and the reinforcements triggers failure mechanisms such as fiber fracture, crack deflection, among others. Biological nanocomposites sometimes exhibit higher toughness than synthetic nanocomposites due to their hierarchical organization. This arrangement triggers failure modes such as mineral bridging and delamination. This review summarizes and classifies systematically the failure mechanisms involved in these nanocomposites. These failures modes are compared for a better understanding and to provide new design criteria for the development of novel bioinspired polymer nanocomposites with enhanced mechanical properties.

AB - Synthetic polymer nanocomposites display enhanced toughness and energy absorption with regard to unreinforced polymers. The interaction between the polymeric matrix and the reinforcements triggers failure mechanisms such as fiber fracture, crack deflection, among others. Biological nanocomposites sometimes exhibit higher toughness than synthetic nanocomposites due to their hierarchical organization. This arrangement triggers failure modes such as mineral bridging and delamination. This review summarizes and classifies systematically the failure mechanisms involved in these nanocomposites. These failures modes are compared for a better understanding and to provide new design criteria for the development of novel bioinspired polymer nanocomposites with enhanced mechanical properties.

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A comparison between the failure modes observed in biological and synthetic polymer nanocomposites

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Keywords

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