Symmetry breaking induces polarized bandgaps and anomalous elastic wave behavior in gyroid lattices

Document Type

Article

Publication Date

1-1-2026

Abstract

We investigate the elastic wave dispersion of surface-based gyroid lattices and analyze how introducing material and geometric asymmetry affects their behavior. First, we show that unmodified (high-symmetry) gyroid lattices exhibit multiple degeneracies in their dispersion relations, preventing bandgap formation. To lift these degeneracies, we implement two asymmetry strategies: (1) Material asymmetry, by assigning different stiffness or density to distinct regions of the unit cell; and (2) Geometric asymmetry, by scaling the lattice unequally along coordinate axes to create anisotropic “gyroid-derived” shapes. Bloch–Floquet analysis of the infinite periodic lattices reveals that both approaches open new bandgaps. Material-asymmetric gyroids develop polarized-directional bandgaps that block one shear polarization in specific directions, and for moderate stiffness or density contrast, produce a “fluid-like” regime in which both shear polarizations (S 1 and S 2) are strongly attenuated, allowing only longitudinal (P) waves. Geometrically asymmetric gyroids likewise exhibit directional bandgaps and, at low frequencies, display anomalous propagation: shear wave phase velocities exceed longitudinal wave velocities—a reversal of the usual hierarchy. Computational homogenization confirms that these anomalies arise from anisotropic effective stiffness coefficients C44 and C66 surpassing C11 along certain axes. Overall, our results demonstrate that deliberate material or geometric asymmetry in gyroid lattices enables precise tailoring of bandgaps and wave-speed hierarchies, offering an effective approach for the design of architected metamaterials for vibration isolation and wave control.

Publication Title

Wave Motion

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