Bifurcation in electrostatic resistive drift wave turbulence
Date
2007-10-26
Authors
Numata, Ryusuke
Ball, Rowena
Dewar, Robert L.
Journal Title
Journal ISSN
Volume Title
Publisher
American Institute of Physics (AIP)
Abstract
The Hasegawa-Wakatani equations, coupling plasma density and electrostatic
potential through an approximation to the physics of parallel electron motions,
are a simple model that describes resistive drift wave turbulence. We present
numerical analyses of bifurcation phenomena in the model that provide new
insights into the interactions between turbulence and zonal flows in the
tokamak plasma edge region. The simulation results show a regime where, after
an initial transient, drift wave turbulence is suppressed through zonal flow
generation. As a parameter controlling the strength of the turbulence is tuned,
this zonal flow dominated state is rapidly destroyed and a turbulence-dominated
state re-emerges. The transition is explained in terms of the Kelvin-Helmholtz
stability of zonal flows. This is the first observation of an upshift of
turbulence onset in the resistive drift wave system, which is analogous to the
well-known Dimits shift in turbulence driven by ion temperature gradients.
Description
Keywords
Keywords: Approximation algorithms; Bifurcation (mathematics); Computer simulation; Mathematical models; Numerical analysis; Parameter estimation; Thermal gradients; Tokamak devices; Drift wave turbulence; Electrostatic potential; Kelvin-Helmholtz stability; Coulom
Citation
Collections
Source
Physics of Plasmas
Type
Journal article
Book Title
Entity type
Access Statement
License Rights
Restricted until
Downloads
File
Description
Published Version