image: The comparison of simulations and experimental plots in the case of selective valley excitation of the K1' state. Black arrows marking the propagation direction and dashed triangular lines demarcating the structures.
Credit: ©Science China Press
In a recent experimental study, researchers have demonstrated the existence of valley vortex states within water wave crystals. This achievement marks a significant advancement in the study of topological phenomena in classical wave systems and draws parallels with similar observations made in photonic crystals. By drawing analogies between 2D Maxwell's equations and water wave equations, this research enables the adaptation of techniques from photonic crystals and metamaterials to the study of water waves.
The research team created a system of water wave crystals using triangular scatterers assembled into a larger equilateral triangle. By adjusting the spatial symmetry of the scatterers through rotation, the team was able to selectively excite water wave valley states via an angular momentum matching mechanism. These states, characterized by vortex features and associated orbital angular momentum, introduce a novel degree of freedom for water wave manipulation.
By utilizing simulation and meticulously designed experimental setups, the study provides a comprehensive analysis of valley vortex states in water waves. The remarkable correlation between simulations and experimental results underscores the potential of water waves as a compelling analog for exploring topological wave behaviors. The simplicity of the water wave experiments, coupled with the conspicuous nature of the phenomena, positions water waves as a compelling analog for exploring a broad spectrum of topological wave behaviors.
In addition to the fundamental research implications, this study also demonstrates potential applications for water wave valley vortex states in ocean energy extraction, marine engineering, and the development of coastal infrastructures. The chirality of the vortex array can be controlled by the chirality of the excitation source, introducing a new degree of freedom for manipulating water waves and directing energy to specific locations.
The research team hopes that this study will spur cross-disciplinary inquiry into the practical applications of topological phenomena and open new avenues for future research in this field.