2025-11-13
Dynamic Self-Loops in Networks of Passive and Active Binary Elements
Publication
Publication
Phys. Rev. Lett. , Volume 135 - Issue 20 p. 207402: 1- 7
Models of coupled binary elements capture memory effects in complex dissipative materials, such as transient responses or sequential computing, when their interactions are chosen appropriately. However, for random interactions, self-loops—cyclic transition sequences incompatible with dissipative dynamics—dominate the response and undermine statistical approaches. Here we reveal that self-loops originate from energy injection and limit cycles in the underlying physical system. We, furthermore, introduce interaction ensembles that strongly suppress or completely eliminate self-loops, allowing statistical studies of memory in large dissipative systems. Our Letter opens a route toward a unified description of passive and active multistable materials using hysteron models.
| Additional Metadata | |
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| American Physical Society (APS) | |
| European Research Council (ERC) | |
| doi.org/10.1103/x1b1-rynn | |
| Phys. Rev. Lett. | |
| Organisation | Mechanical Metamaterials |
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Baconnier, P., Teunisse, M., & van Hecke, M. (2025). Dynamic Self-Loops in Networks of Passive and Active Binary Elements. Phys. Rev. Lett., 135(20), 207402: 1–7. doi:10.1103/x1b1-rynn |
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