Resilient Layered Structures in a Fluctuating Vortex Array

Layered profile structures, or staircases, have been observed in several systems, including drift-wave turbulence near marginality. The simplest type of staircase occurs in passive scalar advection by an array of convection cells, due to the existence of two disparate time scales, the cell turn-over and the diffusion times. To better represent physics of dynamic drift-wave turbulence, we adopt a novel model of a fluctuating vortex array as a basis for a series of numerical experiments. We study staircase persistence and resiliency. By systematically scattering the elements of the vortex array, we show that staircase profiles form and are resilient over a broad range of modest Reynolds numbers. We find that scalar concentration flows around vortices, thus staircase barriers form first and scalar concentration “homogenizes” in vortices later. We also examine the case of active scalar staircase formation. The dynamics of the active scalar are comparable to that of magnetic fields in flux expulsion, where fields are expelled to cell boundaries and stabilize the staircase cells. The active scalar system manifests a novel feedback mechanism that reinforces global staircase structure and self-organization. We show that the spontaneous reinforcement of the cell array structure in the presence of fluctuations occurs only for a narrow range of magnetic field strength. These numerical results can be applied to applications where layered structures occur, such as astrophysical systems and laboratory plasmas.