Figure 1

The effective sound velocities calculated with VAMD-based EMT and with MST, respectively, compared with the experimentally measured effective sound velocity in a 2D phononic crystal composed of Al cylinders arranged in a hexagonal lattice in air, plotted as a function of the filling ratio of Al cylinders. $V_1$ is the sound velocity in air. Here the frequency of sound is 600 Hz, the Al cylinders have a maximum diameter of 3.175 cm, with a hexagonal lattice constant of 6.35 cm. The wavelength of sound in air, 57 cm, is thus much larger than either the cylinder diameter or the lattice constant. The wavelengths of sound in Al, 10.68 m for longitudinal wave and 5.19 m for transverse wave, are even larger. The use of VAMD in the effective medium prediction causes the large discrepancy seen in the figure.Reuse & Permissions

Figure 2

(a) MST-calculated displacement field intensities in the phononic crystal composed of Al cylinders arranged in a hexagonal lattice in air with the filling ratio of Al cylinders being 0.36. Blue is low field intensity, and red is high field intensity. The wave vector is along the $y$ direction, and $a$ is the lattice constant. It is seen that the wave amplitude is nearly zero inside the Al cylinders. Decreasing the frequency further does not alter this fact. (b) The same for PMMA cylinders in water. Wave field is seen to be much more homogeneous than that in (a).Reuse & Permissions

Figure 3

The Berryman effective mass density normalized with the VAMD for three different phononic crystals composed of Al cylinders in air, PMMA cylinders in water, and air cylinders in water, plotted as a function of the filling ratio $f$ of the cylinder inclusions. $D_1$ is the mass density of the matrix, and $D_2$ is the mass density of inclusions.Reuse & Permissions