Abstract
Abstract Modeling the behavior of magnetohydrodynamic waves in a range of magnetic geometries mimicking solar atmospheric waveguides, from photospheric flux tubes to coronal loops, can offer a valuable contribution to the field of solar magneto-seismology. The present study uses an analytical approach to derive the dispersion relation for magneto-acoustic waves in a magnetic slab of homogeneous plasma enclosed on its two sides by semi-infinite plasma of different densities, temperatures, and magnetic field strengths, providing an asymmetric plasma environment. This is a step further in the generalization of the classic magnetic slab model, which is symmetric about the slab, was developed by Roberts, and is an extension of the work by Allcock & Erdélyi where a magnetic slab is sandwiched in an asymmetric nonmagnetic plasma environment. In contrast to the symmetric case, the dispersion relation governing the asymmetric slab cannot be factorized into separate sausage and kink eigenmodes. The solutions obtained resemble these well-known modes; however, their properties are now mixed. Therefore we call these modes quasi-sausage and quasi-kink modes. If conditions on the two sides of the slab do not differ strongly, then a factorization of the dispersion relation can be achieved for the further analytic study of various limiting cases representing a solar environment. In the current paper, we examine the incompressible limit in detail and demonstrate its possible application to photospheric magnetic bright points. After the introduction of a mechanical analogy, we reveal a relationship between the external plasma and magnetic parameters, which allows for the existence of quasi-symmetric modes.
Highlights
The solar atmosphere is a dynamic and inhomogeneous medium with plenty of structuring that enables the propagation of a wide range of magnetohydrodynamic (MHD) waves
Theoretical and practical interest in MHD waves is motivated by fundamental questions of solar physics, namely understanding the physical processes contributing to the heating of the solar atmosphere and diagnosing the highly structured and stratified atmosphere
The magnetic slab model was further generalized by Allcock & Erdélyi (2017), who investigated the emerging wave physics that arise from setting different thermodynamic equilibrium conditions for the two sides of the slab; that is, the external nonmagnetic medium is asymmetric
Summary
The solar atmosphere is a dynamic and inhomogeneous medium with plenty of structuring that enables the propagation of a wide range of magnetohydrodynamic (MHD) waves. Theoretical and practical interest in MHD waves is motivated by fundamental questions of solar physics, namely understanding the physical processes contributing to the heating of the solar atmosphere and diagnosing the highly structured and stratified atmosphere These two tasks are interwoven, as the heating process(es) likely depend on the local plasma equilibrium (De Moortel & Browning 2015). The magnetic slab model was further generalized by Allcock & Erdélyi (2017), who investigated the emerging wave physics that arise from setting different thermodynamic equilibrium conditions for the two sides of the slab; that is, the external nonmagnetic medium is asymmetric. Edwin & Roberts (1982) investigated the propagation of magneto-acoustic waves along a magnetic slab in a symmetric magnetic environment.
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