Fast and Alfvén waves driven by azimuthal footpoint motions

Groof, A. De; Paes, Koen; Goossens, Marcel

doi:10.1051/0004-6361:20020203

Cited by 27 publications

(10 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Beautiful examples of mode coupling and quasi-modes can be found in the work on foot point driving by e.g. De Groof and , De Groof (2001) andDe Groof et al (2002). The quasi-modes and resonant damping are robust phenomena as shown by Terradas et al (2008) for complicated plasma structures.…”

Section: Quasi-modes In Ideal and Eigenmodes In Resistive Mhdmentioning

confidence: 90%

See 1 more Smart Citation

Resonant MHD Waves in the Solar Atmosphere

2010

View full text Add to dashboard Cite

The linear theory of MHD resonant waves in inhomogeneous plasmas is reviewed. The review starts from discussing the properties of driven resonant MHD waves. The dissipative solutions in Alfvén and slow dissipative layers are presented. The important concept of connection formulae is introduced. Next, we proceed on to non-stationary resonant MHD waves. The relation between quasi-modes of ideal MHD and eigenmodes of dissipative MHD are discussed. The solution describing the wave motion in non-stationary dissipative layers is given. It is shown that the connection formulae remain valid for nonstationary resonant MHD waves. The initial-value problem for resonant MHD waves is considered. The application of theory of resonant MHD waves to solar physics is discussed.

show abstract

Section: Quasi-modes In Ideal and Eigenmodes In Resistive Mhdmentioning

confidence: 90%

“…De Groof and Goossens and De Groof 2001;De Groof et al 2002). Resonant MHD waves are important in relation to damped oscillations observed in prominences (see e.g.…”

Section: Introductionmentioning

confidence: 99%

Resonant MHD Waves in the Solar Atmosphere

2010

View full text Add to dashboard Cite

show abstract

“…The analysis is restricted to azimuthally polarized footpoint motions so that only Alfvén waves are directly excited to couple to fast magneto-acoustic waves at later times. In the companion paper De Groof et al (2002) (hereafter referred to as Paper I), the behaviour of the MHD waves is studied in case of a monochromatic driver. In the present study, the effects of a more realistic random driver are investigated.…”

mentioning

confidence: 99%

Fast and Alfvén waves driven by azimuthal footpoint motions

Groof

Goossens

2002

A&A

Self Cite

View full text Add to dashboard Cite

Abstract. The excitation of Alfvén and fast magneto-acoustic waves in coronal loops driven by footpoint motions is studied in linear, ideal MHD. The analysis is restricted to azimuthally polarized footpoint motions so that only Alfvén waves are directly excited to couple to fast magneto-acoustic waves at later times. In the companion paper De Groof et al. (2002) (hereafter referred to as Paper I), the behaviour of the MHD waves is studied in case of a monochromatic driver. In the present study, the effects of a more realistic random driver are investigated. First, we consider loops of equal length and width in order to limit the number of quasi-modes in the frequency range of the driver so that the influence of quasi-modes in the system can easily be detected. In contrast to the single resonant surface which was found in case of a periodic driver (see Paper I), a random pulse train excites a variety of resonant Alfvén waves and consequently the small length scales built up are spread over the whole width of the loop. The specific effects of the quasi-modes are not so easily recognized as for radial footpoint motions (De Groof & Goossens 2000) since the resonances corresponding to directly and indirectly excited Alfvén waves are mixed together. In the second part of the paper, longer loops are considered. Since more quasi-modes are involved, the resonant surfaces are more numerous and widely spread throughout the whole loop volume. On the other hand, it takes more time for the MHD waves to cross the loop and to form standing waves. Nevertheless this negative effect does not have too much impact since the simulations show that after a small time interval, resonant surfaces are created all over the loop, with length scales which are short enough for effective dissipation.

show abstract

“…The driving condition is applied to the lower z boundary to simulate excitation by footpoint motions (e.g., De Groof et al 2002) and prescribes the x and y components of velocity to have a time dependence based on a single period displacement of the loop axis in the x direction. The spatial dependence of the driver is based on a 2D dipole.…”

Section: Modelmentioning

confidence: 99%

Coupled Alfvén and kink oscillations in an inhomogeneous corona

Pascoe¹,

Wright²,

Moortel³

2010

Proc. IAU

View full text Add to dashboard Cite

Abstract. We perform 3D numerical simulations of footpoint-driven transverse waves propagating in a low β plasma. The presence of inhomogeneities in the density profile leads to the coupling of the driven kink mode to Alfvén modes by resonant absorption. The decay of the propagating kink wave as energy is transferred to the local Alfvén mode is in good agreement with a modified interpretation of the analytical expression derived for standing kink modes. This coupling may account for the damping of transverse velocity perturbation waves which have recently been observed to be ubiquitous in the solar corona.

show abstract

Fast and Alfvén waves driven by azimuthal footpoint motions

Cited by 27 publications

References 25 publications

Resonant MHD Waves in the Solar Atmosphere

Resonant MHD Waves in the Solar Atmosphere

Fast and Alfvén waves driven by azimuthal footpoint motions

Coupled Alfvén and kink oscillations in an inhomogeneous corona

Contact Info

Product

Resources

About