Zonostrophic instability driven by discrete particle noise
Abstract
The consequences of discrete particle noise for a system possessing a possibly unstable collective mode are discussed. It is argued that a zonostrophic instability (of homogeneous turbulence to the formation of zonal flows) occurs just below the threshold for linear instability. The scenario provides a new interpretation of the random forcing that is ubiquitously invoked in stochastic models such as the second-order cumulant expansion (CE2) or stochastic structural instability theory (SSST); neither intrinsic turbulence nor coupling to extrinsic turbulence is required. A representative calculation of the zonostrophic neutral curve is made for a simple two-field model of toroidal ion-temperature-gradient-driven modes. To the extent that the damping of zonal flows is controlled by the ion--ion collision rate, the point of zonostrophic instability is independent of that rate.
Cite
@article{arxiv.1611.08231,
title = {Zonostrophic instability driven by discrete particle noise},
author = {D. A. St-Onge and J. A. Krommes},
journal= {arXiv preprint arXiv:1611.08231},
year = {2017}
}
Comments
13 pages, 3 figures