Modelling phase locking of large-scale modes
Paper in proceeding, 2021

Turbulence is often characterized by energetic couplings between different scales of a flow. However, in the context of turbulence driven transport, such as the case of magnetically confined fusion plasmas or the diffusion of cosmic rays, typical flow structures are identified by dominant modes and the global turbulent state is approximated by a superposition of linear contributions (waves in general). These theoretical studies consider the amplitudes of the fluctuating quantities but disregard the dynamics of the phases by using the so-called random-phase approximation (RPA) for which the existence of a Chirikov-like criterion for the onset of wave stochasticity is assumed. In this approximation one assumes that the dynamical amplitudes have a slow variation compared to the rapid change of the phases. It has been observed that the phase dynamic shows significant departure from the well-known RPA assumptions, with phases locking occasionally (but not in the dissipative high-k range). In non-linear turbulent flow however, three-body interactions between the phases of the various modes is of importance. We will consider examples of synchronization in different fluid system such as Burgers and Navier-Stokes turbulence and in more advanced models such as those for Edge Localized Modes (ELMs) in tokamaks which remain a critical issue for plasma stability and the lifetime of fusion reactors such as ITER.

Fusion

Large scale modes

Phase synchronization

Author

Johan Anderson

Chalmers, Space, Earth and Environment

Sara Moradi

Nuclear Engineering

Bulletin of the Americal Physical Society

Vol. 63 ZO06.00001

63rd Annual Meeting of the APS Division of Plasma Physics
Pittsburgh, USA,

Roots

Basic sciences

Subject Categories

Other Physics Topics

Fluid Mechanics and Acoustics

Fusion, Plasma and Space Physics

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Latest update

2/1/2022 1