The stress transfer mechanism of nacre-like composites under off-axis tensile loading

Peng Jiang; Guangming Xia; Shi Bai; Dongfang Xu; Jixiang Qi; Xun Xiong; Xianben Ren; Ying Li

doi:10.1007/s10409-024-24547-x

The stress transfer mechanism of nacre-like composites under off-axis tensile loading

Peng Jiang, Guangming Xia, Shi Bai, Dongfang Xu, Jixiang Qi, Xun Xiong, Xianben Ren^*, Ying Li

^*Corresponding author for this work

Institute of Advanced Structure Technology

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

Abstract

Nacre exhibits excellent mechanical properties attributed to the staggered alignment of inorganic minerals and bio-organic materials. This study aims to understand how stress transfers from macro-scale loading conditions to the staggered architecture, revealing multiple stress transfer modes in nacre-like composites under off-axis tensile loading conditions. We propose an innovative off-axis tension-shear chain model, which predicts the trend of the equivalent modulus. Systematic optimization reveals a counter-intuitive result: the equivalent modulus at a certain angle can be smaller than the equivalent moduli in both principal directions, and this phenomenon differs from the monotonic behavior commonly observed in continuous fiber composite materials.

Translated title of the contribution	偏轴拉伸下贝壳状复合材料的应力传递机制
Original language	English
Article number	424547
Journal	Acta Mechanica Sinica/Lixue Xuebao
Volume	42
Issue number	2
DOIs	http://doi.org/10.1007/s10409-024-24547-x
Publication status	Published - Feb 2026

Keywords

Architected materials
Bioinspired
Composites
Load transfer
Nacre

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abstract = "Nacre exhibits excellent mechanical properties attributed to the staggered alignment of inorganic minerals and bio-organic materials. This study aims to understand how stress transfers from macro-scale loading conditions to the staggered architecture, revealing multiple stress transfer modes in nacre-like composites under off-axis tensile loading conditions. We propose an innovative off-axis tension-shear chain model, which predicts the trend of the equivalent modulus. Systematic optimization reveals a counter-intuitive result: the equivalent modulus at a certain angle can be smaller than the equivalent moduli in both principal directions, and this phenomenon differs from the monotonic behavior commonly observed in continuous fiber composite materials.",

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AU - Bai, Shi

AU - Xu, Dongfang

AU - Qi, Jixiang

AU - Xiong, Xun

AU - Ren, Xianben

AU - Li, Ying

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AB - Nacre exhibits excellent mechanical properties attributed to the staggered alignment of inorganic minerals and bio-organic materials. This study aims to understand how stress transfers from macro-scale loading conditions to the staggered architecture, revealing multiple stress transfer modes in nacre-like composites under off-axis tensile loading conditions. We propose an innovative off-axis tension-shear chain model, which predicts the trend of the equivalent modulus. Systematic optimization reveals a counter-intuitive result: the equivalent modulus at a certain angle can be smaller than the equivalent moduli in both principal directions, and this phenomenon differs from the monotonic behavior commonly observed in continuous fiber composite materials.

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The stress transfer mechanism of nacre-like composites under off-axis tensile loading

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