Abstract
While phononic crystals can be theoretically modeled with a variety of analytical and numerical methods, the practical realization and comprehensive characterization of complex designs is often challenging. This is especially important for the nearly limitless possibilities of periodic, three-dimensional structures. In this contribution, we take a look at these design and fabrication challenges of different 3D phononic elements based on recent research using additive manufacturing. Different fabrication technologies introduce specific limitations in terms of, e.g., material choices, minimum feature size, aspect ratios, or support requirements that have to be taken into account during design and theoretical modeling. We discuss advantages and disadvantages of additive technologies suitable for millimeter and sub-millimeter feature sizes. Furthermore, we present comprehensive experimental characterization of finite, simple cubic lattices in terms of wave polarization and propagation direction to demonstrate the substantial differences between complete phononic band gap and application oriented directional band gaps of selected propagation modes.
Highlights
Phononic crystals (PnC) comprise a periodic arrangement of acoustic scatterers in a one, two, or three-dimensional lattice
Reproducible fabrication samples with sub-millimeter feature sizes and lattice constants down to one millimeter have been realized for all our simple cubic unit cell designs
We present results for different propagation directions as well as acoustic wave modes to build a comprehensive picture of 3D phononic crystal behavior
Summary
Phononic crystals (PnC) comprise a periodic arrangement of acoustic scatterers in a one-, two-, or three-dimensional lattice. These scattering centers exhibit different acoustic properties, primarily density and speed of sound, than the surrounding matrix material. From early phononic crystal research onwards, several groups utilized clever assembly methods to build simple three-dimensional arrangements, typically consisting of solid spheres embedded in a soft or liquid matrix [3,4,5,6,7,8,9]. Various limitations of additive manufacturing technologies must be taken into account when creating complex unit cell designs. These limitations include, Crystals 2017, 11, 348; doi:10.3390/cryst7110348 www.mdpi.com/journal/crystals
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