Bibcode
Arregui, I.; Asensio Ramos, A.; Pascoe, D. J.
Bibliographical reference
The Astrophysical Journal Letters, Volume 769, Issue 2, article id. L34, 6 pp. (2013).
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6
2013
Citations
26
Refereed citations
25
Description
We present a Bayesian seismology inversion technique for propagating
magnetohydrodynamic transverse waves observed in coronal waveguides. The
technique uses theoretical predictions for the spatial damping of
propagating kink waves in transversely inhomogeneous coronal waveguides.
It combines wave amplitude damping length scales along the waveguide
with theoretical results for resonantly damped propagating kink waves to
infer the plasma density variation across the oscillating structures.
Provided that the spatial dependence of the velocity amplitude along the
propagation direction is measured and the existence of two different
damping regimes is identified, the technique would enable us to fully
constrain the transverse density structuring, providing estimates for
the density contrast and its transverse inhomogeneity length scale.
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