Controllable Interlocking from Irregularity in Two-Phase Composites

TL;DR

This paper introduces a method to design two-phase composites with controllable interlocking by varying particle irregularity and arrangement, inspired by natural materials, to enhance mechanical properties like strength and toughness.

Contribution

It presents a stochastic network growth algorithm to generate composites with tunable interlocking based on coordination number, linking irregularity to controllability of interlocking behavior.

Findings

Interlocking increases with irregularity and lower coordination.

Higher coordination leads to more sliding and less interlocking.

Controllability of interlocking is achieved through simple parameter adjustments.

Abstract

Natural materials often feature a combination of soft and stiff phases, arranged to achieve excellent mechanical properties, such as high strength and toughness. Many natural materials have even independently evolved to have similar structures to obtain these properties. For example, interlocking structures are observed in many strong and tough natural materials, across a wide range of length scales. Inspired by these materials, we present a class of two-phase composites with controllable interlocking. The composites feature tessellations of stiff particles connected by a soft matrix and we control the degree of interlocking through irregularity of particle size, geometry and arrangement. We generate the composites through stochastic network growth, using an algorithm which connects a hexagonal grid of nodes according to a coordination number, defined as the average number of connections per node. The generated network forms the soft matrix phase of the composites, while the areas enclosed by the network form the stiff reinforcing particles. At low coordination, composites feature highly polydisperse particles with irregular geometries, which are arranged non-periodically. In response to loading, these particles interlock with each other and primarily rotate and deform to accommodate non-uniform kinematic constraints from adjacent particles. In contrast, higher coordination composites feature more monodisperse particles with uniform geometries, which collectively slide. We then show how to control the degree of interlocking as a function of coordination number alone, demonstrating how irregularity facilitates controllability.