Topologically protected steady cycles in an icelike mechanical metamaterial

Competing ground states may lead to topologically constrained excitations such as domain walls or quasipartides, which govern metastable states and their dynamics. Domain walls and more exotic topological excitations are well studied in magnetic systems such as artificial spin ice, in which nanoscale magnetic dipoles are placed on geometrically frustrated lattices, giving rise to highly degenerate ground states. We propose a mechanical spin-ice constructed from a lattice of floppy, bistable square unit cells. We compare the domain wall excitations that arise in this metamaterial to their magnetic counterparts, finding that new behaviors emerge in this overdamped mechanical system. By tuning the ratios of the internal elements of the unit cell, we control the curvature and propagation speed of internal domain walls. We change the domain wall morphology from a binary, strictly spinlike regime, to a more continuous, elastic regime. In the elastic regime, we inject, manipulate, and expel domain walls via textured forcing at the boundaries. The system exhibits dynamical hysteresis, and we find a first-order dynamical transition as a function of the driving frequency. We demonstrate a forcing protocol that produces multiple, topologically distinct steady cycles, which are protected by the differences in their internal domain wall arrangements. These distinct steady cycles rapidly proliferate as the complexity of the applied forcing texture is increased, thus suggesting that such mechanical systems could serve as useful model systems to study multistability, glassiness, and memory in materials.

Automated summary

Competing ground states can lead to topologically constrained excitations like domain walls or quasipartides, which govern metastable states and their dynamics. This study proposes a mechanical spin ice system with bistable unit cells, and shows new behaviors emerging in this overdamped mechanical system. By controlling the ratios of internal elements, the morphology and propagation speed of internal domain walls can be manipulated, and different steady cycles are produced by textured forcing, suggesting the system could be useful for studying multistability, glassiness, and memory in materials.