On the late phase of relaxation of two-dimensional fluids: turbulence of unitons

TL;DR

This paper explores the intermediate turbulent states of two-dimensional fluids and plasmas using a unified analytical framework based on models like unitons, revealing their common structure and dynamics.

Contribution

It introduces a novel approach connecting various models to describe the pre-relaxation turbulence states in 2D fluids and plasmas, emphasizing the role of unitons.

Findings

Unified description of turbulence using multiple models

Derivation of the sinh-Poisson equation for asymptotic states

Identification of unitons as key dynamic solutions

Abstract

The two-dimensional ideal fluid and the plasma confined by a strong magnetic field exhibit an intrinsic tendency to organization due to the inverse spectral cascade. In the asymptotic states reached at relaxation the turbulence has vanished and there are only coherent vortical structures. We are interested in the regime that precedes these ordered flow patterns, in which there still is turbulence and imperfect but robust structures have emerged. To develop an analytical description we propose to start from the stationary coherent states and (in the direction opposite to relaxation) explore the space of configurations before the extremum of the functional that defines the structures has been reached. We find necessary to assemble different but related models: point-like vortices, its field theoretical formulation as interacting matter and gauge fields, chiral model and surfaces with constant mean curvature. These models are connected by the similar ability to describe randomly interacting coherent structures. They derive exactly the same equation for the asymptotic state (sinh-Poisson equation, confirmed by numerical calculation of fluid flows). The chiral model, to which one can arrive from self-duality equation of the field theoretical model for fluid and from constant mean curvature surface equations, appears to be the suitable analytical framework. Its solutions, the unitons, aquire dynamics when the system is not at the extremum of the action. In the present work we provide arguments that the underlying common nature of these models can be used to develop an approach to fluid and plasma states of turbulence interacting with structures.