Abstract: Faraday waves are capillary ripples that form on the surface of a fluid being subject to vertical shaking. Although it is well known that the form and shape of the waves pattern depend on driving amplitude and frequency, only recent studies discovered the existence of a horizontal velocity field at the surface, called Faraday flow, which exhibits attributes of two-dimensional turbulence. However, despite the increasing attention towards the inverse energy flux in the Faraday flow and other not strictly two-dimensional systems, very little is known about the velocity fields developing beneath the fluid surface. In this study planar velocity fields are measured by means of particle image velocimetry (PIV) with high spatial and temporal resolution on the water surface and below it. A sudden drop in velocity is observed immediately below the water surface, such that at 5 mm below the water surface the mean absolute velocities are already about 6.5 times smaller than the surface velocity. Additionally, the flow structures below the surface are found to comprise much larger spatial scales than those on the surface. These large structures are also found to be slow and temporarily persistent, as proven by analysing the autocorrelation of the velocity fields in time.

The article can be accessed via: <link https: arxiv.org abs>arxiv.org/abs/1911.11208