4.6 Article

Linear Mode Decomposition in Magnetohydrodynamics Revisited

Journal

ASTROPHYSICAL JOURNAL SUPPLEMENT SERIES
Volume 268, Issue 1, Pages -

Publisher

IOP Publishing Ltd
DOI: 10.3847/1538-4365/acdf5d

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Small-amplitude fluctuations in the magnetized solar wind are typically measured by a single spacecraft. Resolving these fluctuations into their constituent fundamental MHD modal components is an ongoing challenge. This study introduces a new method that identifies different modes and computes phase information, providing valuable insights into turbulence in the solar wind.
Small-amplitude fluctuations in the magnetized solar wind are measured typically by a single spacecraft. In the magnetohydrodynamics (MHD) description, fluctuations are typically expressed in terms of the fundamental modes admitted by the system. An important question is how to resolve an observed set of fluctuations, typically plasma moments such as the density, velocity, pressure, and magnetic field fluctuations, into their constituent fundamental MHD modal components. Despite its importance in understanding the basic elements of waves and turbulence in the solar wind, this problem has not yet been fully resolved. Here, we introduce a new method that identifies between wave modes and advected structures such as magnetic islands or entropy modes and computes the phase information associated with the eligible MHD modes. The mode-decomposition method developed here identifies the admissible modes in an MHD plasma from a set of plasma and magnetic field fluctuations measured by a single spacecraft at a specific frequency and an inferred wavenumber k(m). We present data from three typical intervals measured by the Wind and Solar Orbiter spacecraft at similar to 1 au and show how the new method identifies both propagating (wave) and nonpropagating (structures) modes, including entropy and magnetic island modes. This allows us to identify and characterize the separate MHD modes in an observed plasma parcel and to derive wavenumber spectra of entropic density, fast and slow magnetosonic, Alfvenic, and magnetic island fluctuations for the first time. These results help identify the fundamental building blocks of turbulence in the magnetized solar wind.

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