Two-dimensional honeycomb lattice structure for underwater acoustic cloaking using pentamode materials

Abstract: This research article presents an innovative and novel approach to achieve underwater acoustic cloaking using a two-dimensional honeycomb lattice structure with pentamode materials in the kHz frequency range. Underwater acoustic cloaking holds substantial importance in various applications, such as marine engineering, imaging, and military operations, making the development of an efficient underwater acoustic shell imperative. The proposed cloak consists of a pentamode titanium material honeycomb lattice embed… Show more

“…artificially designed and optimized to achieve extraordinary physical properties that natural materials do not possess, such as single negativity [1][2][3] (negative mass or negative modulus) or double negativity [4][5][6] (negative mass and modulus), negative refraction [7,8], etc, enabling special wave propagation and wave control of sound waves. These unique properties make AMs have wide-ranging applications prospects in areas such as sound wave control [9,10], acoustic invisibility [11][12][13], and acoustic imaging [14][15][16].…”

Application of machine learning on the design of acoustic metamaterials and phonon crystals: a review

“…artificially designed and optimized to achieve extraordinary physical properties that natural materials do not possess, such as single negativity [1][2][3] (negative mass or negative modulus) or double negativity [4][5][6] (negative mass and modulus), negative refraction [7,8], etc, enabling special wave propagation and wave control of sound waves. These unique properties make AMs have wide-ranging applications prospects in areas such as sound wave control [9,10], acoustic invisibility [11][12][13], and acoustic imaging [14][15][16].…”

Application of machine learning on the design of acoustic metamaterials and phonon crystals: a review