Title: Transition Graphs of Interacting Hysterons: Structure, Design, Organization and Statistics

Abstract: Collections of bistable elements called hysterons provide a powerful model to capture the sequential response and memory effects of frustrated, multistable media in the athermal, quasistatic limit. While a century of work has elucidated, in great detail, the properties of ensembles of non-interacting hysterons - the so-called Preisach model - comparatively little is known about the behavior and properties of interacting hysterons. Here we discuss a general framework for interacting hysterons, focussing on the relation between the design parameters that specify the hysterons and their interactions, and the resulting transition graphs (t-graphs). We show how the structure of such t-graphs can be thought of as being composed of a scaffold that is dressed by (avalanche) transitions selected from finite binary trees. Moreover, we provide a systematic framework to straightforwardly determine the design inequalities for a given t-graph, and discuss an effective method to determine if a certain t-graph topology is realizable by a set of interacting hysterons. Altogether, our work builds on the Preisach model by generalizing the hysteron-dependent switching fields to the state-dependent switching fields. As a result, while in the Preisach model, the main loop identifies the critical hysterons that trigger a transition, in the case of interacting hysterons, the scaffold contains this critical information and assumes a central role in determining permissible transitions. In addition, our work suggests strategies to deal with the combinatorial explosion of the number and variety of t-graphs for interacting hysterons. This approach paves the way for a deeper theoretical understanding of the properties and statistics of t-graphs, and opens a route to materializing complex pathways, memory effects and embodied computations in (meta)materials based on interacting hysterons.