Details

Autor(en) / Beteiligte

• McManus, Michael D.
• Verniero, Jaye
• Bale, Stuart D.
• Bowen, Trevor A.
• Larson, Davin E.
• Kasper, Justin C.
• Livi, Roberto
• Matteini, Lorenzo
• Rahmati, Ali
• Romeo, Orlando
• Whittlesey, Phyllis
• Woolley, Thomas

Titel

Density and Velocity Fluctuations of Alpha Particles in Magnetic Switchbacks

Ist Teil von

• The Astrophysical journal, 2022-07, Vol.933 (1), p.43

Ort / Verlag

Goddard Space Flight Center: The American Astronomical Society

Erscheinungsjahr

2022

Quelle

EZB Electronic Journals Library

Beschreibungen/Notizen

• Magnetic switchbacks, or sudden reversals in the magnetic field’s radial direction, are one of the more striking observations of the Parker Solar Probe (PSP) in its mission thus far. While their precise production mechanisms are still unknown, the two main theories are via interchange reconnection events and in situ generation. In this work, density and abundance variations of alpha particles are studied inside and outside individual switchbacks. We find no consistent compositional differences in the alpha particle abundance ratio, nαp, inside versus outside switchbacks, nor do we observe any signature when separating the switchbacks according to Vαp/Vpw, the ratio of the alpha–proton differential speed to the wave phase speed (the speed at which the switchback is traveling). We argue that these measurements cannot be used to rule in favor of one production mechanism over the other, due to the distance between PSP and the postulated interchange reconnection events. In addition, we examine the 3D velocity fluctuations of protons and alpha particles within individual switchbacks. While switchbacks are always associated with increases in proton velocity, alpha velocities may be enhanced, unchanged, or decrease. This is due to the interplay between Vpw and Vαp, with the Alfvénic motion of the alpha particles vanishing as the difference |Vpw – Vαp| decreases. We show how the Alfvénic motion of both the alphas and the protons through switchbacks can be understood as an approximately rigid arm rotation about the location of the wave frame, and illustrate that the wave frame can therefore be estimated using particle measurements alone, via sphere fitting.