Unveiling mussel plaque core ductility: the role of pore distribution and hierarchical structure

TL;DR

This study investigates how the pore distribution and hierarchical structure of mussel plaque cores influence their high ductility, using SEM analysis and phase-field modelling to reveal failure mechanisms and structural effects.

Contribution

It introduces a detailed analysis of pore distribution effects and hierarchical structures on mussel plaque ductility through combined SEM imaging and advanced simulation methods.

Findings

Large pores follow a lognormal size distribution with uniform spatial distribution.

Increasing pore size reduces ductility, strength, and strain energy.

Hierarchical porous structures significantly enhance ductility by 40-60%."

Abstract

The mussel thread-plaque system exhibits strong adhesion and high ductility, allowing it to adhere to various surfaces. While the microstructure of plaques has been thoroughly studied, the effect of their unique porous structure on ductility remains unclear. This study firstly investigated the porous structure of mussel plaque cores using scanning electron microscopy (SEM). Two-dimensional (2D) porous representative volume elements (RVEs) with scaled distribution parameters were generated, and the calibrated phase-field modelling method was applied to analyse the effect of the pore distribution and multi-scale porous structure on the failure mechanism of porous RVEs. The SEM analysis revealed that large-scale pores exhibited a lognormal size distribution and a uniform spatial distribution. Simulations showed that increasing the normalised mean radius value of the large-scale pore distribution can statistically lead to a decreasing trend in ductility, strength and strain energy, but cannot solely determine their values. The interaction between pores can lead to two different failure modes under the same pore distribution: progressive failure mode and sudden failure mode. Additionally, the hierarchical structure of multi-scale porous RVEs can further increase ductility by 40%-60% compared to single-scale porous RVEs by reducing stiffness, highlighting the hierarchical structure could be another key factor contributing to the high ductility. These findings deepen our understanding of how the pore distribution and multi-scale porous structure in mussel plaques contribute to their high ductility and affect other mechanical properties, providing valuable insights for the future design of highly ductile biomimetic materials.