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Main Authors: Malaspina, David M., Halekas, Jasper, Bercic, Laura, Larson, Davin, Whittlesey, Phyllis, Bale, Stuart D., Bonnell, John W., de Wit, Thierry Dudok, Ergun, Robert E., Howes, Gregory, Goetz, Keith, Goodrich, Katherine, Harvey, Peter R., MacDowall, Robert J., Pulupa, Marc, Case, Anthony W., Kasper, Justin C., Korreck, Kelly E., Livi, Roberto, Stevens, Michael L.
Format: Preprint
Published: 2019
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Online Access:https://arxiv.org/abs/1912.06793
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author Malaspina, David M.
Halekas, Jasper
Bercic, Laura
Larson, Davin
Whittlesey, Phyllis
Bale, Stuart D.
Bonnell, John W.
de Wit, Thierry Dudok
Ergun, Robert E.
Howes, Gregory
Goetz, Keith
Goodrich, Katherine
Harvey, Peter R.
MacDowall, Robert J.
Pulupa, Marc
Case, Anthony W.
Kasper, Justin C.
Korreck, Kelly E.
Livi, Roberto
Stevens, Michael L.
author_facet Malaspina, David M.
Halekas, Jasper
Bercic, Laura
Larson, Davin
Whittlesey, Phyllis
Bale, Stuart D.
Bonnell, John W.
de Wit, Thierry Dudok
Ergun, Robert E.
Howes, Gregory
Goetz, Keith
Goodrich, Katherine
Harvey, Peter R.
MacDowall, Robert J.
Pulupa, Marc
Case, Anthony W.
Kasper, Justin C.
Korreck, Kelly E.
Livi, Roberto
Stevens, Michael L.
contents Data from the first two orbits of the Sun by Parker Solar Probe reveal that the solar wind sunward of 50 solar radii is replete with plasma waves and instabilities. One of the most prominent plasma wave power enhancements in this region appears near the electron cyclotron frequency (f_ce). Most of this wave power is concentrated in electric field fluctuations near 0.7 f_ce and f_ce, with strong harmonics of both frequencies extending above f_ce. At least two distinct, often concurrent, wave modes are observed, preliminarily identified as electrostatic whistler-mode waves and electron Bernstein waves. Wave intervals range in duration from a few seconds to hours. Both the amplitudes and number of detections of these near-f_ce waves increase significantly with decreasing distance to the Sun, suggesting that they play an important role in the evolution of electron populations in the near-Sun solar wind. Correlations are found between the detection of these waves and properties of solar wind electron populations, including electron core drift, implying that these waves play a role in regulating the heat flux carried by solar wind electrons. Observation of these near-f_ce waves is found to be strongly correlated with near-radial solar wind magnetic field configurations with low levels of magnetic turbulence. A scenario for the growth of these waves is presented which implies that regions of low-turbulence near-radial magnetic field are a prominent feature of solar wind structure near the Sun.
format Preprint
id arxiv_https___arxiv_org_abs_1912_06793
institution arXiv
publishDate 2019
record_format arxiv
spellingShingle Plasma Waves near the Electron Cyclotron Frequency in the near-Sun Solar Wind
Malaspina, David M.
Halekas, Jasper
Bercic, Laura
Larson, Davin
Whittlesey, Phyllis
Bale, Stuart D.
Bonnell, John W.
de Wit, Thierry Dudok
Ergun, Robert E.
Howes, Gregory
Goetz, Keith
Goodrich, Katherine
Harvey, Peter R.
MacDowall, Robert J.
Pulupa, Marc
Case, Anthony W.
Kasper, Justin C.
Korreck, Kelly E.
Livi, Roberto
Stevens, Michael L.
Space Physics
Solar and Stellar Astrophysics
Data from the first two orbits of the Sun by Parker Solar Probe reveal that the solar wind sunward of 50 solar radii is replete with plasma waves and instabilities. One of the most prominent plasma wave power enhancements in this region appears near the electron cyclotron frequency (f_ce). Most of this wave power is concentrated in electric field fluctuations near 0.7 f_ce and f_ce, with strong harmonics of both frequencies extending above f_ce. At least two distinct, often concurrent, wave modes are observed, preliminarily identified as electrostatic whistler-mode waves and electron Bernstein waves. Wave intervals range in duration from a few seconds to hours. Both the amplitudes and number of detections of these near-f_ce waves increase significantly with decreasing distance to the Sun, suggesting that they play an important role in the evolution of electron populations in the near-Sun solar wind. Correlations are found between the detection of these waves and properties of solar wind electron populations, including electron core drift, implying that these waves play a role in regulating the heat flux carried by solar wind electrons. Observation of these near-f_ce waves is found to be strongly correlated with near-radial solar wind magnetic field configurations with low levels of magnetic turbulence. A scenario for the growth of these waves is presented which implies that regions of low-turbulence near-radial magnetic field are a prominent feature of solar wind structure near the Sun.
title Plasma Waves near the Electron Cyclotron Frequency in the near-Sun Solar Wind
topic Space Physics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/1912.06793