Programmable and robust static topological solitons in mechanical metamaterials

Yafei Zhang, Bo Li, Q. S. Zheng, Guy M. Genin, C. Q. Chen

Research output: Contribution to journalArticlepeer-review

83 Scopus citations

Abstract

Solitary, persistent wave packets called solitons hold potential to transfer information and energy across a wide range of spatial and temporal scales in physical, chemical, and biological systems. Mechanical solitons characteristically emerge either as a single wave packet or uncorrelated propagating topological entities through space and/or time, but these are notoriously difficult to control. Here, we report a theoretical framework for programming static periodic topological solitons into a metamaterial, and demonstrate its implementation in real metamaterials computationally and experimentally. The solitons are excited by deformation localizations under quasi-static compression, and arise from buckling-induced kink-antikink bands that provide domain separation barriers. The soliton number and wavelength demonstrate a previously unreported size-dependence, due to intrinsic length scales. We identify that these unanticipated solitons stem from displacive phase transitions with periodic topological excitations captured by the well-known φ4 theory. Results reveal pathways for robust regularizations of stochastic responses of metamaterials.

Original languageEnglish
Article number5605
JournalNature communications
Volume10
Issue number1
DOIs
StatePublished - Dec 1 2019

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