The Properties of Lion Roars and Electron Dynamics in Mirror Mode Waves Observed by the Magnetospheric MultiScale Mission

H. Breuillard; O. Le Contel; T. Chust; M. Berthomier; A. Retino; D. L. Turner; R. Nakamura; W. Baumjohann; G. Cozzani; F. Catapano; A. Alexandrova; L. Mirioni; D. B. Graham; M. R. Argall; D. Fischer; F. D. Wilder; D. J. Gershman; A. Varsani; P. A. Lindqvist; Yu V. Khotyaintsev; G. Marklund; R. E. Ergun; K. A. Goodrich; N. Ahmadi; J. L. Burch; R. B. Torbert; G. Needell; M. Chutter; D. Rau; I. Dors; C. T. Russell; W. Magnes; R. J. Strangeway; K. R. Bromund; H. Wei; F. Plaschke; B. J. Anderson; G. Le; T. E. Moore; B. L. Giles; W. R. Paterson; C. J. Pollock; J. C. Dorelli; L. A. Avanov; Y. Saito; B. Lavraud; S. A. Fuselier; B. H. Mauk; I. J. Cohen; J. F. Fennell

doi:10.1002/2017JA024551

The Properties of Lion Roars and Electron Dynamics in Mirror Mode Waves Observed by the Magnetospheric MultiScale Mission

H. Breuillard
, O. Le Contel
, T. Chust
, M. Berthomier
, A. Retino
, D. L. Turner
, R. Nakamura
, W. Baumjohann
, G. Cozzani
, F. Catapano
, A. Alexandrova
, L. Mirioni
, D. B. Graham
, M. R. Argall
, D. Fischer
, F. D. Wilder
, D. J. Gershman
, A. Varsani
, P. A. Lindqvist
, Yu V. Khotyaintsev

G. Marklund, R. E. Ergun, K. A. Goodrich, N. Ahmadi, J. L. Burch, R. B. Torbert, G. Needell, M. Chutter, D. Rau, I. Dors, C. T. Russell, W. Magnes, R. J. Strangeway, K. R. Bromund, H. Wei, F. Plaschke, B. J. Anderson, G. Le, T. E. Moore, B. L. Giles, W. R. Paterson, C. J. Pollock, J. C. Dorelli, L. A. Avanov, Y. Saito, B. Lavraud, S. A. Fuselier, B. H. Mauk, I. J. Cohen, J. F. Fennell

Sorbonne Université
The Aerospace Corporation
Space Research Institute
Swedish Institute of Space Physics
University of New Hampshire
University of Colorado Boulder
NASA Goddard Space Flight Center
KTH Royal Institute of Technology
Southwest Research Institute
Institute of Geophysics and Planetary Physics, University of California
Johns Hopkins University Applied Physics Laboratory
ISAS/JAXA
IRAP/CNRS

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Mirror mode waves are ubiquitous in the Earth's magnetosheath, in particular behind the quasi-perpendicular shock. Embedded in these nonlinear structures, intense lion roars are often observed. Lion roars are characterized by whistler wave packets at a frequency ∼100 Hz, which are thought to be generated in the magnetic field minima. In this study, we make use of the high time resolution instruments on board the Magnetospheric MultiScale mission to investigate these waves and the associated electron dynamics in the quasi-perpendicular magnetosheath on 22 January 2016. We show that despite a core electron parallel anisotropy, lion roars can be generated locally in the range 0.05–0.2f_ce by the perpendicular anisotropy of electrons in a particular energy range. We also show that intense lion roars can be observed up to higher frequencies due to the sharp nonlinear peaks of the signal, which appear as sharp spikes in the dynamic spectra. As a result, a high sampling rate is needed to estimate correctly their amplitude, and the latter might have been underestimated in previous studies using lower time resolution instruments. We also present for the first-time 3-D high time resolution electron velocity distribution functions in mirror modes. We demonstrate that the dynamics of electrons trapped in the mirror mode structures are consistent with the Kivelson and Southwood (1996) model. However, these electrons can also interact with the embedded lion roars: first signatures of electron quasi-linear pitch angle diffusion and possible signatures of nonlinear interaction with high-amplitude wave packets are presented. These processes can lead to electron untrapping from mirror modes.

langue originale	Anglais
Pages (de - à)	93-103
Nombre de pages	11
journal	Journal of Geophysical Research: Space Physics
Volume	123
Numéro de publication	1
Les DOIs	https://doi.org/10.1002/2017JA024551
état	Publié - 1 janv. 2018

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10.1002/2017JA024551

Contient cette citation

Breuillard, H., Le Contel, O., Chust, T., Berthomier, M., Retino, A., Turner, D. L., Nakamura, R., Baumjohann, W., Cozzani, G., Catapano, F., Alexandrova, A., Mirioni, L., Graham, D. B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. A., ... Fennell, J. F. (2018). The Properties of Lion Roars and Electron Dynamics in Mirror Mode Waves Observed by the Magnetospheric MultiScale Mission. Journal of Geophysical Research: Space Physics, 123(1), 93-103. https://doi.org/10.1002/2017JA024551

@article{9a0f44ae63924cccb0647af2c0866a05,

title = "The Properties of Lion Roars and Electron Dynamics in Mirror Mode Waves Observed by the Magnetospheric MultiScale Mission",

abstract = "Mirror mode waves are ubiquitous in the Earth's magnetosheath, in particular behind the quasi-perpendicular shock. Embedded in these nonlinear structures, intense lion roars are often observed. Lion roars are characterized by whistler wave packets at a frequency ∼100 Hz, which are thought to be generated in the magnetic field minima. In this study, we make use of the high time resolution instruments on board the Magnetospheric MultiScale mission to investigate these waves and the associated electron dynamics in the quasi-perpendicular magnetosheath on 22 January 2016. We show that despite a core electron parallel anisotropy, lion roars can be generated locally in the range 0.05–0.2fce by the perpendicular anisotropy of electrons in a particular energy range. We also show that intense lion roars can be observed up to higher frequencies due to the sharp nonlinear peaks of the signal, which appear as sharp spikes in the dynamic spectra. As a result, a high sampling rate is needed to estimate correctly their amplitude, and the latter might have been underestimated in previous studies using lower time resolution instruments. We also present for the first-time 3-D high time resolution electron velocity distribution functions in mirror modes. We demonstrate that the dynamics of electrons trapped in the mirror mode structures are consistent with the Kivelson and Southwood (1996) model. However, these electrons can also interact with the embedded lion roars: first signatures of electron quasi-linear pitch angle diffusion and possible signatures of nonlinear interaction with high-amplitude wave packets are presented. These processes can lead to electron untrapping from mirror modes.",

keywords = "lion roars, magnetosheath, mirror modes, nonlinear waves, particle trapping, wave-particle interaction",

author = "H. Breuillard and O. Le Contel and T. Chust and M. Berthomier and A. Retino and Turner, \{D. L.\} and R. Nakamura and W. Baumjohann and G. Cozzani and F. Catapano and A. Alexandrova and L. Mirioni and Graham, \{D. B.\} and Argall, \{M. R.\} and D. Fischer and Wilder, \{F. D.\} and Gershman, \{D. J.\} and A. Varsani and Lindqvist, \{P. A.\} and Khotyaintsev, \{Yu V.\} and G. Marklund and Ergun, \{R. E.\} and Goodrich, \{K. A.\} and N. Ahmadi and Burch, \{J. L.\} and Torbert, \{R. B.\} and G. Needell and M. Chutter and D. Rau and I. Dors and Russell, \{C. T.\} and W. Magnes and Strangeway, \{R. J.\} and Bromund, \{K. R.\} and H. Wei and F. Plaschke and Anderson, \{B. J.\} and G. Le and Moore, \{T. E.\} and Giles, \{B. L.\} and Paterson, \{W. R.\} and Pollock, \{C. J.\} and Dorelli, \{J. C.\} and Avanov, \{L. A.\} and Y. Saito and B. Lavraud and Fuselier, \{S. A.\} and Mauk, \{B. H.\} and Cohen, \{I. J.\} and Fennell, \{J. F.\}",

year = "2018",

month = jan,

day = "1",

doi = "10.1002/2017JA024551",

language = "English",

volume = "123",

pages = "93--103",

journal = "Journal of Geophysical Research: Space Physics",

issn = "2169-9402",

number = "1",

}

Breuillard, H, Le Contel, O, Chust, T, Berthomier, M , Retino, A, Turner, DL, Nakamura, R, Baumjohann, W, Cozzani, G, Catapano, F, Alexandrova, A, Mirioni, L, Graham, DB, Argall, MR, Fischer, D, Wilder, FD, Gershman, DJ, Varsani, A, Lindqvist, PA, Khotyaintsev, YV, Marklund, G, Ergun, RE, Goodrich, KA, Ahmadi, N, Burch, JL, Torbert, RB, Needell, G, Chutter, M, Rau, D, Dors, I, Russell, CT, Magnes, W, Strangeway, RJ, Bromund, KR, Wei, H, Plaschke, F, Anderson, BJ, Le, G, Moore, TE, Giles, BL, Paterson, WR, Pollock, CJ, Dorelli, JC, Avanov, LA, Saito, Y, Lavraud, B, Fuselier, SA, Mauk, BH, Cohen, IJ & Fennell, JF 2018, 'The Properties of Lion Roars and Electron Dynamics in Mirror Mode Waves Observed by the Magnetospheric MultiScale Mission', Journal of Geophysical Research: Space Physics, VOL. 123, Numéro 1, p. 93-103. https://doi.org/10.1002/2017JA024551

TY - JOUR

T1 - The Properties of Lion Roars and Electron Dynamics in Mirror Mode Waves Observed by the Magnetospheric MultiScale Mission

AU - Breuillard, H.

AU - Le Contel, O.

AU - Chust, T.

AU - Berthomier, M.

AU - Retino, A.

AU - Turner, D. L.

AU - Nakamura, R.

AU - Baumjohann, W.

AU - Cozzani, G.

AU - Catapano, F.

AU - Alexandrova, A.

AU - Mirioni, L.

AU - Graham, D. B.

AU - Argall, M. R.

AU - Fischer, D.

AU - Wilder, F. D.

AU - Gershman, D. J.

AU - Varsani, A.

AU - Lindqvist, P. A.

AU - Khotyaintsev, Yu V.

AU - Marklund, G.

AU - Ergun, R. E.

AU - Goodrich, K. A.

AU - Ahmadi, N.

AU - Burch, J. L.

AU - Torbert, R. B.

AU - Needell, G.

AU - Chutter, M.

AU - Rau, D.

AU - Dors, I.

AU - Russell, C. T.

AU - Magnes, W.

AU - Strangeway, R. J.

AU - Bromund, K. R.

AU - Wei, H.

AU - Plaschke, F.

AU - Anderson, B. J.

AU - Le, G.

AU - Moore, T. E.

AU - Giles, B. L.

AU - Paterson, W. R.

AU - Pollock, C. J.

AU - Dorelli, J. C.

AU - Avanov, L. A.

AU - Saito, Y.

AU - Lavraud, B.

AU - Fuselier, S. A.

AU - Mauk, B. H.

AU - Cohen, I. J.

AU - Fennell, J. F.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - Mirror mode waves are ubiquitous in the Earth's magnetosheath, in particular behind the quasi-perpendicular shock. Embedded in these nonlinear structures, intense lion roars are often observed. Lion roars are characterized by whistler wave packets at a frequency ∼100 Hz, which are thought to be generated in the magnetic field minima. In this study, we make use of the high time resolution instruments on board the Magnetospheric MultiScale mission to investigate these waves and the associated electron dynamics in the quasi-perpendicular magnetosheath on 22 January 2016. We show that despite a core electron parallel anisotropy, lion roars can be generated locally in the range 0.05–0.2fce by the perpendicular anisotropy of electrons in a particular energy range. We also show that intense lion roars can be observed up to higher frequencies due to the sharp nonlinear peaks of the signal, which appear as sharp spikes in the dynamic spectra. As a result, a high sampling rate is needed to estimate correctly their amplitude, and the latter might have been underestimated in previous studies using lower time resolution instruments. We also present for the first-time 3-D high time resolution electron velocity distribution functions in mirror modes. We demonstrate that the dynamics of electrons trapped in the mirror mode structures are consistent with the Kivelson and Southwood (1996) model. However, these electrons can also interact with the embedded lion roars: first signatures of electron quasi-linear pitch angle diffusion and possible signatures of nonlinear interaction with high-amplitude wave packets are presented. These processes can lead to electron untrapping from mirror modes.

AB - Mirror mode waves are ubiquitous in the Earth's magnetosheath, in particular behind the quasi-perpendicular shock. Embedded in these nonlinear structures, intense lion roars are often observed. Lion roars are characterized by whistler wave packets at a frequency ∼100 Hz, which are thought to be generated in the magnetic field minima. In this study, we make use of the high time resolution instruments on board the Magnetospheric MultiScale mission to investigate these waves and the associated electron dynamics in the quasi-perpendicular magnetosheath on 22 January 2016. We show that despite a core electron parallel anisotropy, lion roars can be generated locally in the range 0.05–0.2fce by the perpendicular anisotropy of electrons in a particular energy range. We also show that intense lion roars can be observed up to higher frequencies due to the sharp nonlinear peaks of the signal, which appear as sharp spikes in the dynamic spectra. As a result, a high sampling rate is needed to estimate correctly their amplitude, and the latter might have been underestimated in previous studies using lower time resolution instruments. We also present for the first-time 3-D high time resolution electron velocity distribution functions in mirror modes. We demonstrate that the dynamics of electrons trapped in the mirror mode structures are consistent with the Kivelson and Southwood (1996) model. However, these electrons can also interact with the embedded lion roars: first signatures of electron quasi-linear pitch angle diffusion and possible signatures of nonlinear interaction with high-amplitude wave packets are presented. These processes can lead to electron untrapping from mirror modes.

KW - lion roars

KW - magnetosheath

KW - mirror modes

KW - nonlinear waves

KW - particle trapping

KW - wave-particle interaction

U2 - 10.1002/2017JA024551

DO - 10.1002/2017JA024551

M3 - Article

AN - SCOPUS:85042310063

SN - 2169-9402

VL - 123

SP - 93

EP - 103

JO - Journal of Geophysical Research: Space Physics

JF - Journal of Geophysical Research: Space Physics

IS - 1

ER -

The Properties of Lion Roars and Electron Dynamics in Mirror Mode Waves Observed by the Magnetospheric MultiScale Mission

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