TY - JOUR
T1 - Onset of an energy cascade and nonperiodic behaviour in the nonlinear propagation of mh d waves in the solar atmosphere
AU - Nocera, Lulgl
AU - Priest, Eric R.
PY - 1986/12
Y1 - 1986/12
N2 - We study the nonlinear stability of MHD waves propagating in a two-dimensional, compressible, highly magnetized, viscous plasma. These waves are driven by a weak, shear body force which could be imposed by large scale internal fluctuations present in the solar atmosphere. The effects of anisotropic viscosity (leading to a cubic damping) and of the nonlinear coupling of the Alfven and the magnetoacoustic waves are analysed using Galerkin and multiple-scale analysis: the MHD equations are reduced to a set of nonlinear ordinary differential equations which is then suitably truncated to give a model dynamical system, representing the interaction of two complex Galerkin modes. For propagation oblique to the background magnetic field, analytical integration shows that the lowwavenumber mode is physically unstable. For propagation parallel to the background magnetic field the high-wavenumber wave can undergo saddlenode bifurcations, in way that is similar to the van der Pol oscillator; these bifurcations lead to the appearance of a hysteresis cycle. A numerical integration of the dynamical system shows that a sequence of Hopf bifurcations takes place as the Reynolds number is increased, up to the onset of nonperiodic behaviour. It also shows that energy can be transferred from the lowwavenumber to the high-wavenumber mode.
AB - We study the nonlinear stability of MHD waves propagating in a two-dimensional, compressible, highly magnetized, viscous plasma. These waves are driven by a weak, shear body force which could be imposed by large scale internal fluctuations present in the solar atmosphere. The effects of anisotropic viscosity (leading to a cubic damping) and of the nonlinear coupling of the Alfven and the magnetoacoustic waves are analysed using Galerkin and multiple-scale analysis: the MHD equations are reduced to a set of nonlinear ordinary differential equations which is then suitably truncated to give a model dynamical system, representing the interaction of two complex Galerkin modes. For propagation oblique to the background magnetic field, analytical integration shows that the lowwavenumber mode is physically unstable. For propagation parallel to the background magnetic field the high-wavenumber wave can undergo saddlenode bifurcations, in way that is similar to the van der Pol oscillator; these bifurcations lead to the appearance of a hysteresis cycle. A numerical integration of the dynamical system shows that a sequence of Hopf bifurcations takes place as the Reynolds number is increased, up to the onset of nonperiodic behaviour. It also shows that energy can be transferred from the lowwavenumber to the high-wavenumber mode.
KW - bifurcation theory
KW - Coronal heating
UR - http://www.scopus.com/inward/record.url?scp=84963462927&partnerID=8YFLogxK
U2 - 10.1080/03091928608210096
DO - 10.1080/03091928608210096
M3 - Article
AN - SCOPUS:84963462927
SN - 0309-1929
VL - 37
SP - 193
EP - 218
JO - Geophysical & Astrophysical Fluid Dynamics
JF - Geophysical & Astrophysical Fluid Dynamics
IS - 3
ER -