Switchbacks in the Solar Magnetic Field: Their Evolution, Their Content, and Their Effects on the Plasma

F. S. Mozer; O. V. Agapitov; S. D. Bale; J. W. Bonnell; T. Case; C. C. Chaston; D. W. Curtis; T. Dudok De Wit; K. Goetz; K. A. Goodrich; P. R. Harvey; J. C. Kasper; K. E. Korreck; V. Krasnoselskikh; D. E. Larson; R. Livi; R. J. MacDowall; D. Malaspina; M. Pulupa; M. Stevens; P. L. Whittlesey; J. R. Wygant

doi:10.3847/1538-4365/ab7196

Switchbacks in the Solar Magnetic Field: Their Evolution, Their Content, and Their Effects on the Plasma

F. S. Mozer, O. V. Agapitov, S. D. Bale, J. W. Bonnell, T. Case, C. C. Chaston, D. W. Curtis, T. Dudok De Wit, K. Goetz, K. A. Goodrich, P. R. Harvey, J. C. Kasper, K. E. Korreck, V. Krasnoselskikh, D. E. Larson, R. Livi, R. J. MacDowall, D. Malaspina, M. Pulupa, M. StevensP. L. Whittlesey, J. R. Wygant

Physics and Astronomy (Twin Cities)

Research output: Contribution to journal › Article › peer-review

84 Scopus citations

Abstract

Switchbacks (rotations of the magnetic field) are observed on the Parker Solar Probe. Their evolution, content, and plasma effects are studied in this paper. The solar wind does not receive a net acceleration from switchbacks that it encountered upstream of the observation point. The typical switchback rotation angle increased with radial distance. Significant Poynting fluxes existed inside, but not outside, switchbacks, and the dependence of the Poynting flux amplitude on the switchback radial location and rotation angle is explained quantitatively as being proportional to (B sin(θ))2. The solar wind flow inside switchbacks was faster than that outside due to the frozen-in ions moving with the magnetic structure at the Alfvén speed. This energy gain results from the divergence of the Poynting flux from outside to inside the switchback, which produces a loss of electromagnetic energy on switchback entry and recovery of that energy on exit, with the lost energy appearing in the plasma flow. Switchbacks contain 0.3-10 Hz waves that may result from currents and the Kelvin-Helmholtz instability that occurs at the switchback boundaries. These waves may combine with lower frequency magnetohydrodynamic waves to heat the plasma.

Original language	English (US)
Article number	68
Journal	Astrophysical Journal, Supplement Series
Volume	246
Issue number	2
DOIs	https://doi.org/10.3847/1538-4365/ab7196
State	Published - Feb 2020

Bibliographical note

Publisher Copyright:
© 2020. The Author(s). Published by the American Astronomical Society..

Access

10.3847/1538-4365/ab7196

OpenUrl availability

Full text

Cite this

Mozer, F. S., Agapitov, O. V., Bale, S. D., Bonnell, J. W., Case, T., Chaston, C. C., Curtis, D. W., Wit, T. D. D., Goetz, K., Goodrich, K. A., Harvey, P. R., Kasper, J. C., Korreck, K. E., Krasnoselskikh, V., Larson, D. E., Livi, R., MacDowall, R. J., Malaspina, D., Pulupa, M., ... Wygant, J. R. (2020). Switchbacks in the Solar Magnetic Field: Their Evolution, Their Content, and Their Effects on the Plasma. Astrophysical Journal, Supplement Series, 246(2), Article 68. https://doi.org/10.3847/1538-4365/ab7196

Mozer, FS, Agapitov, OV, Bale, SD, Bonnell, JW, Case, T, Chaston, CC, Curtis, DW, Wit, TDD, Goetz, K, Goodrich, KA, Harvey, PR, Kasper, JC, Korreck, KE, Krasnoselskikh, V, Larson, DE, Livi, R, MacDowall, RJ, Malaspina, D, Pulupa, M, Stevens, M, Whittlesey, PL & Wygant, JR 2020, 'Switchbacks in the Solar Magnetic Field: Their Evolution, Their Content, and Their Effects on the Plasma', Astrophysical Journal, Supplement Series, vol. 246, no. 2, 68. https://doi.org/10.3847/1538-4365/ab7196

@article{f4a43d6e5393478b8f315b5f9ebbd081,

title = "Switchbacks in the Solar Magnetic Field: Their Evolution, Their Content, and Their Effects on the Plasma",

abstract = "Switchbacks (rotations of the magnetic field) are observed on the Parker Solar Probe. Their evolution, content, and plasma effects are studied in this paper. The solar wind does not receive a net acceleration from switchbacks that it encountered upstream of the observation point. The typical switchback rotation angle increased with radial distance. Significant Poynting fluxes existed inside, but not outside, switchbacks, and the dependence of the Poynting flux amplitude on the switchback radial location and rotation angle is explained quantitatively as being proportional to (B sin(θ))2. The solar wind flow inside switchbacks was faster than that outside due to the frozen-in ions moving with the magnetic structure at the Alfv{\'e}n speed. This energy gain results from the divergence of the Poynting flux from outside to inside the switchback, which produces a loss of electromagnetic energy on switchback entry and recovery of that energy on exit, with the lost energy appearing in the plasma flow. Switchbacks contain 0.3-10 Hz waves that may result from currents and the Kelvin-Helmholtz instability that occurs at the switchback boundaries. These waves may combine with lower frequency magnetohydrodynamic waves to heat the plasma.",

author = "Mozer, {F. S.} and Agapitov, {O. V.} and Bale, {S. D.} and Bonnell, {J. W.} and T. Case and Chaston, {C. C.} and Curtis, {D. W.} and Wit, {T. Dudok De} and K. Goetz and Goodrich, {K. A.} and Harvey, {P. R.} and Kasper, {J. C.} and Korreck, {K. E.} and V. Krasnoselskikh and Larson, {D. E.} and R. Livi and MacDowall, {R. J.} and D. Malaspina and M. Pulupa and M. Stevens and Whittlesey, {P. L.} and Wygant, {J. R.}",

note = "Publisher Copyright: {\textcopyright} 2020. The Author(s). Published by the American Astronomical Society..",

year = "2020",

month = feb,

doi = "10.3847/1538-4365/ab7196",

language = "English (US)",

volume = "246",

journal = "Astrophysical Journal, Supplement Series",

issn = "0067-0049",

publisher = "IOP Publishing Ltd.",

number = "2",

}

TY - JOUR

T1 - Switchbacks in the Solar Magnetic Field

T2 - Their Evolution, Their Content, and Their Effects on the Plasma

AU - Mozer, F. S.

AU - Agapitov, O. V.

AU - Bale, S. D.

AU - Bonnell, J. W.

AU - Case, T.

AU - Chaston, C. C.

AU - Curtis, D. W.

AU - Wit, T. Dudok De

AU - Goetz, K.

AU - Goodrich, K. A.

AU - Harvey, P. R.

AU - Kasper, J. C.

AU - Korreck, K. E.

AU - Krasnoselskikh, V.

AU - Larson, D. E.

AU - Livi, R.

AU - MacDowall, R. J.

AU - Malaspina, D.

AU - Pulupa, M.

AU - Stevens, M.

AU - Whittlesey, P. L.

AU - Wygant, J. R.

PY - 2020/2

Y1 - 2020/2

N2 - Switchbacks (rotations of the magnetic field) are observed on the Parker Solar Probe. Their evolution, content, and plasma effects are studied in this paper. The solar wind does not receive a net acceleration from switchbacks that it encountered upstream of the observation point. The typical switchback rotation angle increased with radial distance. Significant Poynting fluxes existed inside, but not outside, switchbacks, and the dependence of the Poynting flux amplitude on the switchback radial location and rotation angle is explained quantitatively as being proportional to (B sin(θ))2. The solar wind flow inside switchbacks was faster than that outside due to the frozen-in ions moving with the magnetic structure at the Alfvén speed. This energy gain results from the divergence of the Poynting flux from outside to inside the switchback, which produces a loss of electromagnetic energy on switchback entry and recovery of that energy on exit, with the lost energy appearing in the plasma flow. Switchbacks contain 0.3-10 Hz waves that may result from currents and the Kelvin-Helmholtz instability that occurs at the switchback boundaries. These waves may combine with lower frequency magnetohydrodynamic waves to heat the plasma.

AB - Switchbacks (rotations of the magnetic field) are observed on the Parker Solar Probe. Their evolution, content, and plasma effects are studied in this paper. The solar wind does not receive a net acceleration from switchbacks that it encountered upstream of the observation point. The typical switchback rotation angle increased with radial distance. Significant Poynting fluxes existed inside, but not outside, switchbacks, and the dependence of the Poynting flux amplitude on the switchback radial location and rotation angle is explained quantitatively as being proportional to (B sin(θ))2. The solar wind flow inside switchbacks was faster than that outside due to the frozen-in ions moving with the magnetic structure at the Alfvén speed. This energy gain results from the divergence of the Poynting flux from outside to inside the switchback, which produces a loss of electromagnetic energy on switchback entry and recovery of that energy on exit, with the lost energy appearing in the plasma flow. Switchbacks contain 0.3-10 Hz waves that may result from currents and the Kelvin-Helmholtz instability that occurs at the switchback boundaries. These waves may combine with lower frequency magnetohydrodynamic waves to heat the plasma.

UR - http://www.scopus.com/inward/record.url?scp=85085085699&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85085085699&partnerID=8YFLogxK

U2 - 10.3847/1538-4365/ab7196

DO - 10.3847/1538-4365/ab7196

M3 - Article

AN - SCOPUS:85085085699

SN - 0067-0049

VL - 246

JO - Astrophysical Journal, Supplement Series

JF - Astrophysical Journal, Supplement Series

IS - 2

M1 - 68

ER -

Switchbacks in the Solar Magnetic Field: Their Evolution, Their Content, and Their Effects on the Plasma

Abstract

Bibliographical note

Access

OpenUrl availability

Other files and links

Fingerprint

Cite this