Modeling phononic band gap in microstructured solids using the Riemann-Cartan geometric framework

Modeling acoustic wave fields in microstructured elastic solids is discussed in the context of the Riemann-Cartan geometry. We consider a scenario where microstructural deformations occur much faster than those of the bulk material. This time-scale separation creates apparent geometric incompatibilities at the macroscopic level, even without any permanent inelastic deformation (at micro or macro-scale) or damage. We formalize this phenomenon using the concept of a non-holonomic tetrads to represent the macroscopic elastic deformations and the associated torsion field to characterize the resulting geometric incompatibilities. The spatial components of the torsion tensor quantify the instantaneous geometric incompatibility of the macroscopic elastic deformations, while its time components capture the inertial effects arising from the reversible energy exchange between the micro and macro scales. A key finding is that the model's dispersion relation predicts the existence of a complete frequency band gap. Furthermore, the governing equations exhibit a notable mathematical analogy to Maxwell's equations which can link the modeling of phononic and photonic metamaterials.