Abstract
Metamaterials are engineered materials that offer the flexibility to manipulate the incident waves leading to exotic applications such as cloaking, extraordinary transmission, sub-wavelength imaging and negative refraction. These concepts have largely been explored in the context of electromagnetic waves. Acoustic metamaterials, similar to their optical counterparts, demonstrate anomalous effective elastic properties. Recent developments have shown that coiling up the propagation path of acoustic wave results in effective elastic response of the metamaterial beyond the natural response of its constituent materials. The effective response of metamaterials is generally evaluated using the ‘S’ parameter retrieval method based on amplitude of the waves. The phase of acoustic waves contains information of wave pressure and particle velocity. Here, we show using finite-element methods that phase reversal of transmitted waves may be used to predict extreme acoustic properties in space coiling metamaterials. This change is the difference in the phase of the transmitted wave with respect to the incident wave. This method is simpler when compared with the more rigorous ‘S’ parameter retrieval method. The inferences drawn using this method have been verified experimentally for labyrinthine metamaterials by showing negative refraction for the predicted band of frequencies.
Highlights
Metamaterials are a class of artificially engineered materials which offer the possibility of achieving effective properties beyond the scope of naturally existing properties of constituent elements
Finite-element methods have been used to calculate the transmitted waves profile of acoustic waves passing through 2D and 3D space coiling metamaterials
The analysis of the transmitted waves shows that phase is developed while traversing through the metamaterial unit
Summary
Metamaterials are a class of artificially engineered materials which offer the possibility of achieving effective properties beyond the scope of naturally existing properties of constituent elements. These are envisioned to have several important applications such as surface wave manipulation, sub-wavelength. The concept of metamaterials was initially developed with an intent to manipulate electromagnetic waves
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