Effect of Spherical Polarization on the Magnetic Spectrum of the Solar Wind

Abstract

Magnetic fluctuations in the solar wind are often observed to maintain constant magnitude of the magnetic field in a manner consistent with spherically-polarized large-amplitude Alfv\'en waves. We investigate the effect of spherical polarization on the magnetic spectral index through a statistical survey of magnetic fluctuations observed by Parker Solar Probe between 20R and 200R. We find that deviations from spherical polarization, i.e., changes in |B| (compressive fluctuations) and one-dimensional discontinuities, have a dramatic effect on the scaling behavior of the turbulent fluctuations. We show that shallow k-3/2 spectra are only observed for constant magnetic field strength, three-dimensional structures, which we identify as large amplitude Alfv\'en waves. The presence of compressive fluctuations coincides with a steepening of the spectrum up to k-5/3. Steeper power law scalings approaching k-2 are observed when the fluctuations are dominated by discontinuities. Near-sun fluctuations are found to be the most spherically polarized, suggesting that this spherical state is fundamental to the generation of the solar wind. With increasing distance from the Sun, fluctuations are found to become less three dimensional and more compressive, which may indicate the breakdown of the Alfv\'enic equilibrium state.