In Situ Signature of Cyclotron Resonant Heating in the Solar Wind
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PhysRevLett.129.165101.pdf
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Author
Bowen, T.A.Chandran, B.D.G.
Squire, J.
Bale, S.D.
Duan, D.
Klein, K.G.
Larson, D.
Mallet, A.
McManus, M.D.
Meyrand, R.
Verniero, J.L.
Woodham, L.D.
Affiliation
Department of Planetary Sciences, Lunar and Planetary Laboratory, University of ArizonaIssue Date
2022
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American Physical SocietyCitation
Bowen, T. A., Chandran, B. D. G., Squire, J., Bale, S. D., Duan, D., Klein, K. G., Larson, D., Mallet, A., McManus, M. D., Meyrand, R., Verniero, J. L., & Woodham, L. D. (2022). In Situ Signature of Cyclotron Resonant Heating in the Solar Wind. Physical Review Letters, 129(16).Journal
Physical Review LettersRights
Copyright © 2022 American Physical Society.Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
The dissipation of magnetized turbulence is an important paradigm for describing heating and energy transfer in astrophysical environments such as the solar corona and wind; however, the specific collisionless processes behind dissipation and heating remain relatively unconstrained by measurements. Remote sensing observations have suggested the presence of strong temperature anisotropy in the solar corona consistent with cyclotron resonant heating. In the solar wind, in situ magnetic field measurements reveal the presence of cyclotron waves, while measured ion velocity distribution functions have hinted at the active presence of cyclotron resonance. Here, we present Parker Solar Probe observations that connect the presence of ion-cyclotron waves directly to signatures of resonant damping in observed proton-velocity distributions using the framework of quasilinear theory. We show that the quasilinear evolution of the observed distribution functions should absorb the observed cyclotron wave population with a heating rate of 10-14 W/m3, indicating significant heating of the solar wind. © 2022 American Physical Society.Note
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0031-9007PubMed ID
36306754Version
Final published versionae974a485f413a2113503eed53cd6c53
10.1103/PhysRevLett.129.165101
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