A Flux-Balanced Fluid Model for Collisional Plasma Edge Turbulence: Model Derivation and Basic Physical Features

TL;DR

This paper introduces a flux-balanced fluid model for collisional plasma edge turbulence, extending the Hasegawa-Wakatani model to better capture electron flux and turbulence features, with validation through numerical simulations.

Contribution

The model improves electron flux treatment and converges to the modified Hasegawa-Mima model in the collisionless limit, enhancing understanding of plasma turbulence dynamics.

Findings

Enhanced turbulence variability and zonal jets in simulations.

Stronger zonal jets observed compared to previous HW models.

Feedback of third-order moments is crucial for equilibrium.

Abstract

We propose a new reduced fluid model for the study of the drift wave -- zonal flow dynamics in magnetically confined plasmas. Our model can be viewed as an extension of the classic Hasegawa-Wakatani (HW) model, and is based on an improved treatment of the electron dynamics parallel to the field lines, to guarantee a balanced electron flux on the magnetic surfaces. Our flux-balanced HW (bHW) model contains the same drift-wave instability as previous HW models, but unlike these models, it converges exactly to the modified Hasegawa-Mima model in the collisionless limit. We rely on direct numerical simulations to illustrate some of the key features of the bHW model, such as the enhanced variability in the turbulent fluctuations, and the existence of stronger and more turbulent zonal jets than the jets observed in other HW models, especially for high plasma resistivity. Our simulations also highlight the crucial role of the feedback of the third-order statistical moments in achieving a statistical equilibrium with strong zonal structures. Finally, we investigate the changes in the observed dynamics when more general dissipation effects are included, and in particular when we include the reduced model for ion Landau damping originally proposed by Wakatani and Hasegawa.