Your search keyword '"Le Contel, O."' showing total 46 results

1. Direct observations of anomalous resistivity and diffusion in collisionless plasma

Author

Graham, D. B., Khotyaintsev, Yu. V., Andre, M., Vaivads, Andris, Divin, A., Drake, J. F., Norgren, C., Le Contel, O., Lindqvist, Per-Arne, Rager, A. C., Gershman, D. J., Russell, C. T., Burch, J. L., Hwang, K. -J, Dokgo, K., Graham, D. B., Khotyaintsev, Yu. V., Andre, M., Vaivads, Andris, Divin, A., Drake, J. F., Norgren, C., Le Contel, O., Lindqvist, Per-Arne, Rager, A. C., Gershman, D. J., Russell, C. T., Burch, J. L., Hwang, K. -J, and Dokgo, K.

Abstract

Coulomb collisions provide plasma resistivity and diffusion but in many low-density astrophysical plasmas such collisions between particles are extremely rare. Scattering of particles by electromagnetic waves can lower the plasma conductivity. Such anomalous resistivity due to wave-particle interactions could be crucial to many processes, including magnetic reconnection. It has been suggested that waves provide both diffusion and resistivity, which can support the reconnection electric field, but this requires direct observation to confirm. Here, we directly quantify anomalous resistivity, viscosity, and cross-field electron diffusion associated with lower hybrid waves using measurements from the four Magnetospheric Multiscale (MMS) spacecraft. We show that anomalous resistivity is approximately balanced by anomalous viscosity, and thus the waves do not contribute to the reconnection electric field. However, the waves do produce an anomalous electron drift and diffusion across the current layer associated with magnetic reconnection. This leads to relaxation of density gradients at timescales of order the ion cyclotron period, and hence modifies the reconnection process. It is suggested that waves can provide both diffusion and resistivity that can potentially support the reconnection electric field in low-density astrophysical plasmas. Here, the authors show, using direct spacecraft measurements, that the waves contribute to anomalous diffusion but do not contribute to the reconnection electric field., QC 20230228

Published

2022

2. Direct observations of energy transfer from resonant electrons to whistler-mode waves in magnetosheath of Earth

Author

Kitamura, N., Amano, T., Omura, Y., Boardsen, S. A., Gershman, D. J., Miyoshi, Y., Kitahara, M., Katoh, Y., Kojima, H., Nakamura, S., Shoji, M., Saito, Y., Yokota, S., Giles, B. L., Paterson, W. R., Pollock, C. J., Barrie, A. C., Skeberdis, D. G., Kreisler, S., Le Contel, O., Russell, C. T., Strangeway, R. J., Lindqvist, Per-Arne, Ergun, R. E., Torbert, R. B., Burch, J. L., Kitamura, N., Amano, T., Omura, Y., Boardsen, S. A., Gershman, D. J., Miyoshi, Y., Kitahara, M., Katoh, Y., Kojima, H., Nakamura, S., Shoji, M., Saito, Y., Yokota, S., Giles, B. L., Paterson, W. R., Pollock, C. J., Barrie, A. C., Skeberdis, D. G., Kreisler, S., Le Contel, O., Russell, C. T., Strangeway, R. J., Lindqvist, Per-Arne, Ergun, R. E., Torbert, R. B., and Burch, J. L.

Abstract

Excitation of whistler-mode waves by cyclotron instability is considered as the likely generation process of the waves. Here, the authors show direct observational evidence for locally ongoing secular energy transfer from the resonant electrons to the whistler-mode waves in Earth's magnetosheath. Electromagnetic whistler-mode waves in space plasmas play critical roles in collisionless energy transfer between the electrons and the electromagnetic field. Although resonant interactions have been considered as the likely generation process of the waves, observational identification has been extremely difficult due to the short time scale of resonant electron dynamics. Here we show strong nongyrotropy, which rotate with the wave, of cyclotron resonant electrons as direct evidence for the locally ongoing secular energy transfer from the resonant electrons to the whistler-mode waves using ultra-high temporal resolution data obtained by NASA's Magnetospheric Multiscale (MMS) mission in the magnetosheath. The nongyrotropic electrons carry a resonant current, which is the energy source of the wave as predicted by the nonlinear wave growth theory. This result proves the nonlinear wave growth theory, and furthermore demonstrates that the degree of nongyrotropy, which cannot be predicted even by that nonlinear theory, can be studied by observations., QC 20221212

Published

2022

3. Thin Current Sheet Behind the Dipolarization Front

Author

Nakamura, R., Baumjohann, W., Nakamura, T. K. M., Panov, E. , V, Schmid, D., Varsani, A., Apatenkov, S., Sergeev, V. A., Birn, J., Nagai, T., Gabrielse, C., André, Mats, Burch, J. L., Carr, C., Dandouras, I. S., Escoubet, C. P., Fazakerley, A. N., Giles, B. L., Le Contel, O., Russell, C. T., Torbert, R. B., Nakamura, R., Baumjohann, W., Nakamura, T. K. M., Panov, E. , V, Schmid, D., Varsani, A., Apatenkov, S., Sergeev, V. A., Birn, J., Nagai, T., Gabrielse, C., André, Mats, Burch, J. L., Carr, C., Dandouras, I. S., Escoubet, C. P., Fazakerley, A. N., Giles, B. L., Le Contel, O., Russell, C. T., and Torbert, R. B.

Abstract

We report a unique conjugate observation of fast flows and associated current sheet disturbances in the near-Earth magnetotail by MMS (Magnetospheric Multiscale) and Cluster preceding a positive bay onset of a small substorm at similar to 14:10 UT, September 8, 2018. MMS and Cluster were located both at X similar to -14 R-E. A dipolarization front (DF) of a localized fast flow was detected by Cluster and MMS, separated in the dawn-dusk direction by similar to 4 R-E,R- almost simultaneously. Adiabatic electron acceleration signatures revealed from the comparison of the energy spectra confirm that both spacecraft encounter the same DF. We analyzed the change in the current sheet structure based on multi-scale multi-point data analysis. The current sheet thickened during the passage of DF, yet, temporally thinned subsequently associated with another flow enhancement centered more on the dawnward side of the initial flow. MMS and Cluster observed intense perpendicular and parallel current in the off-equatorial region mainly during this interval of the current sheet thinning. Maximum field-aligned currents both at MMS and Cluster are directed tailward. Detailed analysis of MMS data showed that the intense field-aligned currents consisted of multiple small-scale intense current layers accompanied by enhanced Hall-currents in the dawn-dusk flow-shear region. We suggest that the current sheet thinning is related to the flow bouncing process and/or to the expansion/activation of reconnection. Based on these mesoscale and small-scale multipoint observations, 3D evolution of the flow and current-sheet disturbances was inferred preceding the development of a substorm current wedge.

Published

2021

4. Upper-Hybrid Waves Driven by Meandering Electrons Around Magnetic Reconnection X Line

Author

Li, Wenya, Khotyaintsev, Yuri V., Tang, B-B, Graham, Daniel B., Norgren, C., Vaivads, A., André, Mats, Le, A., Egedal, J., Dokgo, K., Fujimoto, K., He, J-S, Burch, J. L., Lindqvist, P-A, Ergun, R. E., Torbert, R. B., Le Contel, O., Gershman, D. J., Giles, B. L., Lavraud, B., Fuselier, S., Plaschke, F., Russell, C. T., Guo, X-C, Lu, Q-M, Wang, C., Li, Wenya, Khotyaintsev, Yuri V., Tang, B-B, Graham, Daniel B., Norgren, C., Vaivads, A., André, Mats, Le, A., Egedal, J., Dokgo, K., Fujimoto, K., He, J-S, Burch, J. L., Lindqvist, P-A, Ergun, R. E., Torbert, R. B., Le Contel, O., Gershman, D. J., Giles, B. L., Lavraud, B., Fuselier, S., Plaschke, F., Russell, C. T., Guo, X-C, Lu, Q-M, and Wang, C.

Abstract

Magnetic reconnection is a fundamental process in collisionless space plasma environment, and plasma waves relevant to the kinetic interactions can have a significant impact on the multiscale behavior of reconnection. Here, we present Magnetospheric Multiscale (MMS) observations during an encounter of an X line of symmetric magnetic reconnection in the magnetotail. The X line is characterized by reversals of ion and electron jets and electromagnetic fields, agyrotropic electron velocity distribution functions (VDFs), and an electron-scale current sheet. MMS observe large-amplitude nonlinear upper-hybrid (UH) waves on both sides of the neutral line, and the wave amplitudes have highly localized distribution along the normal direction. The inbound meandering electrons drive the UH waves, releasing the free energy stored from the reconnection electric field along the meandering trajectories. The interaction between the meandering electrons and the UH waves may modify the balance of the reconnection electric field around the X line. Plain Language Summary The electron-scale kinetic physics in the electron diffusion region (EDR) controls how magnetic field lines break and reconnect. Electron crescent, an indicator of EDR, can drive high-frequency electrostatic waves around EDR. For the first time, the upper-hybrid (UH) waves are observed on both sides of the X line and we show the direct association between the UH waves and the reconnection electric field. The strong wave-electron interaction can change the electron-scale dynamics and may modify the reconnection electric field. This study demonstrates that the UH waves may play an important role in controlling the reconnection rate.

Published

2021

5. Kinetic Interaction of Cold and Hot Protons With an Oblique EMIC Wave Near the Dayside Reconnecting Magnetopause

Author

Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., Vinas, A., Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., and Vinas, A.

Abstract

We report observations of the ion dynamics inside an Alfven branch wave that propagates near the reconnecting dayside magnetopause. The measured frequency, wave normal angle and polarization are consistent with the predictions of a dispersion solver. The magnetospheric plasma contains hot protons (keV), cold protons (eV), plus some heavy ions. While the cold protons follow the magnetic field fluctuations and remain frozen-in, the hot protons are at the limit of magnetization. The cold protons exchange energy back and forth, adiabatically, with the wave fields. The cold proton velocity fluctuations contribute to balance the Hall term fluctuations in Ohm's law, and the wave E field has small ellipticity and right-handed polarization. The dispersion solver indicates that increasing the cold proton density facilitates propagation and amplification of these waves at oblique angles, as for the observed wave. Plain Language Summary The Earth's magnetosphere is a very dilute cloud of charged particles that are trapped in the Earth's magnetic field. This cloud is surrounded by the solar wind, another very dilute gas that flows supersonically throughout the solar system. These two plasmas can couple to each other via magnetic reconnection, a fundamental plasma process that occurs at the dayside region of the interface between the two plasmas. When reconnection occurs, large amounts of energy and particles enter the magnetosphere, driving the near Earth space dynamics and generating, for instance, aurorae. The magnetospheric plasma sources are the solar wind and the Earth's ionosphere. Multiple plasma populations can be found inside the Earth's magnetosphere, depending on the plasma origin and its time history, as well as the magnetospheric forcing of the solar wind. In this study, we show how the presence of multiple particle populations at the interface between the solar wind and the magnetosphere modifies the properties of the waves that propagate there. Waves are known to

Published

2021

6. Kinetic Interaction of Cold and Hot Protons With an Oblique EMIC Wave Near the Dayside Reconnecting Magnetopause

Author

Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., Vinas, A., Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., and Vinas, A.

Abstract

We report observations of the ion dynamics inside an Alfven branch wave that propagates near the reconnecting dayside magnetopause. The measured frequency, wave normal angle and polarization are consistent with the predictions of a dispersion solver. The magnetospheric plasma contains hot protons (keV), cold protons (eV), plus some heavy ions. While the cold protons follow the magnetic field fluctuations and remain frozen-in, the hot protons are at the limit of magnetization. The cold protons exchange energy back and forth, adiabatically, with the wave fields. The cold proton velocity fluctuations contribute to balance the Hall term fluctuations in Ohm's law, and the wave E field has small ellipticity and right-handed polarization. The dispersion solver indicates that increasing the cold proton density facilitates propagation and amplification of these waves at oblique angles, as for the observed wave. Plain Language Summary The Earth's magnetosphere is a very dilute cloud of charged particles that are trapped in the Earth's magnetic field. This cloud is surrounded by the solar wind, another very dilute gas that flows supersonically throughout the solar system. These two plasmas can couple to each other via magnetic reconnection, a fundamental plasma process that occurs at the dayside region of the interface between the two plasmas. When reconnection occurs, large amounts of energy and particles enter the magnetosphere, driving the near Earth space dynamics and generating, for instance, aurorae. The magnetospheric plasma sources are the solar wind and the Earth's ionosphere. Multiple plasma populations can be found inside the Earth's magnetosphere, depending on the plasma origin and its time history, as well as the magnetospheric forcing of the solar wind. In this study, we show how the presence of multiple particle populations at the interface between the solar wind and the magnetosphere modifies the properties of the waves that propagate there. Waves are known to

Published

2021

7. Upper-Hybrid Waves Driven by Meandering Electrons Around Magnetic Reconnection X Line

Author

Li, W-Y, Khotyaintsev, Yu, V, Tang, B-B, Graham, D. B., Norgren, C., Vaivads, Andris, Andre, M., Le, A., Egedal, J., Dokgo, K., Fujimoto, K., He, J-S, Burch, J. L., Lindqvist, Per-Arne, Ergun, R. E., Torbert, R. B., Le Contel, O., Gershman, D. J., Giles, B. L., Lavraud, B., Fuselier, S., Plaschke, F., Russell, C. T., Guo, X-C, Lu, Q-M, Wang, C., Li, W-Y, Khotyaintsev, Yu, V, Tang, B-B, Graham, D. B., Norgren, C., Vaivads, Andris, Andre, M., Le, A., Egedal, J., Dokgo, K., Fujimoto, K., He, J-S, Burch, J. L., Lindqvist, Per-Arne, Ergun, R. E., Torbert, R. B., Le Contel, O., Gershman, D. J., Giles, B. L., Lavraud, B., Fuselier, S., Plaschke, F., Russell, C. T., Guo, X-C, Lu, Q-M, and Wang, C.

Abstract

Magnetic reconnection is a fundamental process in collisionless space plasma environment, and plasma waves relevant to the kinetic interactions can have a significant impact on the multiscale behavior of reconnection. Here, we present Magnetospheric Multiscale (MMS) observations during an encounter of an X line of symmetric magnetic reconnection in the magnetotail. The X line is characterized by reversals of ion and electron jets and electromagnetic fields, agyrotropic electron velocity distribution functions (VDFs), and an electron-scale current sheet. MMS observe large-amplitude nonlinear upper-hybrid (UH) waves on both sides of the neutral line, and the wave amplitudes have highly localized distribution along the normal direction. The inbound meandering electrons drive the UH waves, releasing the free energy stored from the reconnection electric field along the meandering trajectories. The interaction between the meandering electrons and the UH waves may modify the balance of the reconnection electric field around the X line. Plain Language Summary The electron-scale kinetic physics in the electron diffusion region (EDR) controls how magnetic field lines break and reconnect. Electron crescent, an indicator of EDR, can drive high-frequency electrostatic waves around EDR. For the first time, the upper-hybrid (UH) waves are observed on both sides of the X line and we show the direct association between the UH waves and the reconnection electric field. The strong wave-electron interaction can change the electron-scale dynamics and may modify the reconnection electric field. This study demonstrates that the UH waves may play an important role in controlling the reconnection rate., QC 20210915

Published

2021

8. Kinetic Interaction of Cold and Hot Protons With an Oblique EMIC Wave Near the Dayside Reconnecting Magnetopause

Author

Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., Vinas, A., Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., and Vinas, A.

Abstract

We report observations of the ion dynamics inside an Alfven branch wave that propagates near the reconnecting dayside magnetopause. The measured frequency, wave normal angle and polarization are consistent with the predictions of a dispersion solver. The magnetospheric plasma contains hot protons (keV), cold protons (eV), plus some heavy ions. While the cold protons follow the magnetic field fluctuations and remain frozen-in, the hot protons are at the limit of magnetization. The cold protons exchange energy back and forth, adiabatically, with the wave fields. The cold proton velocity fluctuations contribute to balance the Hall term fluctuations in Ohm's law, and the wave E field has small ellipticity and right-handed polarization. The dispersion solver indicates that increasing the cold proton density facilitates propagation and amplification of these waves at oblique angles, as for the observed wave. Plain Language Summary The Earth's magnetosphere is a very dilute cloud of charged particles that are trapped in the Earth's magnetic field. This cloud is surrounded by the solar wind, another very dilute gas that flows supersonically throughout the solar system. These two plasmas can couple to each other via magnetic reconnection, a fundamental plasma process that occurs at the dayside region of the interface between the two plasmas. When reconnection occurs, large amounts of energy and particles enter the magnetosphere, driving the near Earth space dynamics and generating, for instance, aurorae. The magnetospheric plasma sources are the solar wind and the Earth's ionosphere. Multiple plasma populations can be found inside the Earth's magnetosphere, depending on the plasma origin and its time history, as well as the magnetospheric forcing of the solar wind. In this study, we show how the presence of multiple particle populations at the interface between the solar wind and the magnetosphere modifies the properties of the waves that propagate there. Waves are known to

Published

2021

9. Comparative Analysis of the Various Generalized Ohm's Law Terms in Magnetosheath Turbulence as Observed by Magnetospheric Multiscale

Author

Stawarz, J. E., Matteini, L., Parashar, T. N., Franci, L., Eastwood, J. P., Gonzalez, C. A., Gingell, I. L., Burch, J. L., Ergun, R. E., Ahmadi, N., Giles, B. L., Gershman, D. J., Le Contel, O., Lindqvist, Per-Arne, Russell, C. T., Strangeway, R. J., Torbert, R. B., Stawarz, J. E., Matteini, L., Parashar, T. N., Franci, L., Eastwood, J. P., Gonzalez, C. A., Gingell, I. L., Burch, J. L., Ergun, R. E., Ahmadi, N., Giles, B. L., Gershman, D. J., Le Contel, O., Lindqvist, Per-Arne, Russell, C. T., Strangeway, R. J., and Torbert, R. B.

Abstract

Decomposing the electric field (E) into the contributions from generalized Ohm's law provides key insight into both nonlinear and dissipative dynamics across the full range of scales within a plasma. Using high-resolution, multispacecraft measurements of three intervals in Earth's magnetosheath from the Magnetospheric Multiscale mission, the influence of the magnetohydrodynamic, Hall, electron pressure, and electron inertia terms from Ohm's law, as well as the impact of a finite electron mass, on the turbulent E spectrum are examined observationally for the first time. The magnetohydrodynamic, Hall, and electron pressure terms are the dominant contributions to E over the accessible length scales, which extend to scales smaller than the electron gyroradius at the greatest extent, with the Hall and electron pressure terms dominating at sub-ion scales. The strength of the nonideal electron pressure contribution is stronger than expected from linear kinetic Alfven waves and a partial antialignment with the Hall electric field is present, linked to the relative importance of electron diamagnetic currents in the turbulence. The relative contribution of linear and nonlinear electric fields scale with the turbulent fluctuation amplitude, with nonlinear contributions playing the dominant role in shaping E for the intervals examined in this study. Overall, the sum of the Ohm's law terms and measured E agree to within similar to 20% across the observable scales. These results both confirm general expectations about the behavior of E in turbulent plasmas and highlight features that should be explored further theoretically., QC 20210412

Published

2021

10. Kinetic Interaction of Cold and Hot Protons With an Oblique EMIC Wave Near the Dayside Reconnecting Magnetopause

Author

Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., Vinas, A., Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., and Vinas, A.

Abstract

We report observations of the ion dynamics inside an Alfven branch wave that propagates near the reconnecting dayside magnetopause. The measured frequency, wave normal angle and polarization are consistent with the predictions of a dispersion solver. The magnetospheric plasma contains hot protons (keV), cold protons (eV), plus some heavy ions. While the cold protons follow the magnetic field fluctuations and remain frozen-in, the hot protons are at the limit of magnetization. The cold protons exchange energy back and forth, adiabatically, with the wave fields. The cold proton velocity fluctuations contribute to balance the Hall term fluctuations in Ohm's law, and the wave E field has small ellipticity and right-handed polarization. The dispersion solver indicates that increasing the cold proton density facilitates propagation and amplification of these waves at oblique angles, as for the observed wave. Plain Language Summary The Earth's magnetosphere is a very dilute cloud of charged particles that are trapped in the Earth's magnetic field. This cloud is surrounded by the solar wind, another very dilute gas that flows supersonically throughout the solar system. These two plasmas can couple to each other via magnetic reconnection, a fundamental plasma process that occurs at the dayside region of the interface between the two plasmas. When reconnection occurs, large amounts of energy and particles enter the magnetosphere, driving the near Earth space dynamics and generating, for instance, aurorae. The magnetospheric plasma sources are the solar wind and the Earth's ionosphere. Multiple plasma populations can be found inside the Earth's magnetosphere, depending on the plasma origin and its time history, as well as the magnetospheric forcing of the solar wind. In this study, we show how the presence of multiple particle populations at the interface between the solar wind and the magnetosphere modifies the properties of the waves that propagate there. Waves are known to

Published

2021

11. Kinetic Interaction of Cold and Hot Protons With an Oblique EMIC Wave Near the Dayside Reconnecting Magnetopause

Author

Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., Vinas, A., Toledo-Redondo, S., Lee, J. H., Vines, S. K., Turner, D. L., Allen, R. C., André, Mats, Boardsen, S. A., Burch, J. L., Denton, R. E., Fu, H. S., Fuselier, S. A., Gershman, D. J., Giles, B., Graham, Daniel B., Kitamura, N., Khotyaintsev, Yuri V., Lavraud, B., Le Contel, O., Li, W. Y., Moore, T. E., Navarro, E. A., Porti, J., Salinas, A., and Vinas, A.

Abstract

We report observations of the ion dynamics inside an Alfven branch wave that propagates near the reconnecting dayside magnetopause. The measured frequency, wave normal angle and polarization are consistent with the predictions of a dispersion solver. The magnetospheric plasma contains hot protons (keV), cold protons (eV), plus some heavy ions. While the cold protons follow the magnetic field fluctuations and remain frozen-in, the hot protons are at the limit of magnetization. The cold protons exchange energy back and forth, adiabatically, with the wave fields. The cold proton velocity fluctuations contribute to balance the Hall term fluctuations in Ohm's law, and the wave E field has small ellipticity and right-handed polarization. The dispersion solver indicates that increasing the cold proton density facilitates propagation and amplification of these waves at oblique angles, as for the observed wave. Plain Language Summary The Earth's magnetosphere is a very dilute cloud of charged particles that are trapped in the Earth's magnetic field. This cloud is surrounded by the solar wind, another very dilute gas that flows supersonically throughout the solar system. These two plasmas can couple to each other via magnetic reconnection, a fundamental plasma process that occurs at the dayside region of the interface between the two plasmas. When reconnection occurs, large amounts of energy and particles enter the magnetosphere, driving the near Earth space dynamics and generating, for instance, aurorae. The magnetospheric plasma sources are the solar wind and the Earth's ionosphere. Multiple plasma populations can be found inside the Earth's magnetosphere, depending on the plasma origin and its time history, as well as the magnetospheric forcing of the solar wind. In this study, we show how the presence of multiple particle populations at the interface between the solar wind and the magnetosphere modifies the properties of the waves that propagate there. Waves are known to

Published

2021

12. Whistler Waves Driven by Field-Aligned Streaming Electrons in the Near-Earth Magnetotail Reconnection

Author

Ren, Y., Dai, L., Li, W., Tao, X., Wang, C., Tang, B., Lavraud, B., Wu, Y., Burch, J. L., Giles, B. L., Le Contel, O., Torbert, R. B., Russell, C. T., Strangeway, R. J., Ergun, R. E., Lindqvist, Per-Arne, Ren, Y., Dai, L., Li, W., Tao, X., Wang, C., Tang, B., Lavraud, B., Wu, Y., Burch, J. L., Giles, B. L., Le Contel, O., Torbert, R. B., Russell, C. T., Strangeway, R. J., Ergun, R. E., and Lindqvist, Per-Arne

Abstract

We analyze Magnetospheric Multiscale Mission observations of whistler waves and associated electron field-aligned crescent distribution in the vicinity of the magnetotail near-Earth X-line. The whistler waves propagate outward from the X-line in the neutral sheet. The associated field-aligned streaming electrons exhibit a crescent-like shape, with an inverse slope (df/d vertical bar v(parallel to)vertical bar > 0) at 1-5 keV. The parallel phase velocity of the waves is in the range (1-5 keV) of the inverse slope of the field-aligned crescents in the velocity space. We demonstrate that the observed whistler waves are driven by the electron field-aligned crescents through Landau resonance. The cyclotron resonance is at the high-energy tail with negligible free energy of pitch angle anisotropy in these events., QC 20190903

Published

2019

13. Properties of the Turbulence Associated with Electron-only Magnetic Reconnection in Earth's Magnetosheath

Author

Stawarz, J. E., Eastwood, J. P., Phan, T. D., Gingell, I. L., Shay, M. A., Burch, J. L., Ergun, R. E., Giles, B. L., Gershman, D. J., Le Contel, O., Lindqvist, Per-Arne, Russell, C. T., Strangeway, R. J., Torbert, R. B., Argall, M. R., Fischer, D., Magnes, W., Franci, L., Stawarz, J. E., Eastwood, J. P., Phan, T. D., Gingell, I. L., Shay, M. A., Burch, J. L., Ergun, R. E., Giles, B. L., Gershman, D. J., Le Contel, O., Lindqvist, Per-Arne, Russell, C. T., Strangeway, R. J., Torbert, R. B., Argall, M. R., Fischer, D., Magnes, W., and Franci, L.

Abstract

Turbulent plasmas generate intense current structures, which have long been suggested as magnetic reconnection sites. Recent Magnetospheric Multiscale observations in Earth's magnetosheath revealed a novel form of reconnection where the dynamics only couple to electrons, without ion involvement. It was suggested that such dynamics were driven by magnetosheath turbulence. In this study, the fluctuations are examined to determine the properties of the turbulence and if a signature of reconnection is present in the turbulence statistics. The study reveals statistical properties consistent with plasma turbulence with a correlation length of similar to 10 ion inertial lengths. When reconnection is more prevalent, a steepening of the magnetic spectrum occurs at the length scale of the reconnecting current sheets. The statistics of intense currents suggest the prevalence of electron-scale current sheets favorable for electron reconnection. The results support the hypothesis that electron reconnection is driven by turbulence and highlight diagnostics that may provide insight into reconnection in other turbulent plasmas., QC 20211026

Published

2019

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

Author

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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Fennell, J. F., 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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., and Fennell, J. F.

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.

Published

2018

15. Electron Jet Detected by MMS at Dipolarization Front

Author

Liu, C. M., Fu, H. S., Vaivads, Andris, Khotyaintsev, Yuri V., Gershman, D. J., Hwang, K-J, Chen, Z. Z., Cao, D., Xu, Y., Yang, J., Peng, F. Z., Huang, S. Y., Burch, J. L., Giles, B. L., Ergun, R. E., Russell, C. T., Lindqvist, P-A, Le Contel, O., Liu, C. M., Fu, H. S., Vaivads, Andris, Khotyaintsev, Yuri V., Gershman, D. J., Hwang, K-J, Chen, Z. Z., Cao, D., Xu, Y., Yang, J., Peng, F. Z., Huang, S. Y., Burch, J. L., Giles, B. L., Ergun, R. E., Russell, C. T., Lindqvist, P-A, and Le Contel, O.

Abstract

Using MMS high-resolution measurements, we present the first observation of fast electron jet (V-e similar to 2,000 km/s) at a dipolarization front (DF) in the magnetotail plasma sheet. This jet, with scale comparable to the DF thickness (similar to 0.9 d(i)), is primarily in the tangential plane to the DF current sheet and mainly undergoes the E x B drift motion; it contributes significantly to the current system at the DF, including a localized ring-current that can modify the DF topology. Associated with this fast jet, we observed a persistent normal electric field, strong lower hybrid drift waves, and strong energy conversion at the DF. Such strong energy conversion is primarily attributed to the electron-jet-driven current (E.j(e) approximate to 2 E.j(i)), rather than the ion current suggested in previous studies.

Published

2018

16. Large-Amplitude High-Frequency Waves at Earth's Magnetopause

Author

Graham, D. B., Vaivads, Andris, Khotyaintsev, Yu. V., Andre, M., Le Contel, O., Malaspina, D. M., Lindqvist, Per-Arne, Wilder, F. D., Ergun, R. E., Gershman, D. J., Giles, B. L., Magnes, W., Russell, C. T., Burch, J. L., Torbert, R. B., Graham, D. B., Vaivads, Andris, Khotyaintsev, Yu. V., Andre, M., Le Contel, O., Malaspina, D. M., Lindqvist, Per-Arne, Wilder, F. D., Ergun, R. E., Gershman, D. J., Giles, B. L., Magnes, W., Russell, C. T., Burch, J. L., and Torbert, R. B.

Abstract

Large-amplitude waves near the electron plasma frequency are found by the Magnetospheric Multiscale (MMS) mission near Earth's magnetopause. The waves are identified as Langmuir and upper hybrid (UH) waves, with wave vectors either close to parallel or close to perpendicular to the background magnetic field. The waves are found all along the magnetopause equatorial plane, including both flanks and close to the subsolar point. The waves reach very large amplitudes, up to 1Vm(-1), and are thus among the most intense electric fields observed at Earth's magnetopause. In the magnetosphere and on the magnetospheric side of the magnetopause the waves are predominantly UH waves although Langmuir waves are also found. When the plasma is very weakly magnetized only Langmuir waves are likely to be found. Both Langmuir and UH waves are shown to have electromagnetic components, which are consistent with predictions from kinetic wave theory. These results show that the magnetopause and magnetosphere are often unstable to intense wave activity near the electron plasma frequency. These waves provide a possible source of radio emission at the magnetopause., QC 20180627

Published

2018

17. New Insights into the Nature of Turbulence in the Earth's Magnetosheath Using Magnetospheric MultiScale Mission Data

Author

Breuillard, H., Matteini, L., Argall, M. R., Sahraoui, F., Andriopoulou, M., Le Contel, O., Retino, A., Mirioni, L., Huang, S. Y., Gershman, D. J., Ergun, R. E., Wilder, F. D., Goodrich, K. A., Ahmadi, N., Yordanova, E., Vaivads, Andris, Turner, D. L., Khotyaintsev, Yu. V., Graham, D. B., Lindqvist, Per-Arne, Chasapis, A., Burch, J. L., Torbert, R. B., Russell, C. T., Magnes, W., Strangeway, R. J., Plaschke, F., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Lavraud, B., Fuselier, S. A., Cohen, I. J., Breuillard, H., Matteini, L., Argall, M. R., Sahraoui, F., Andriopoulou, M., Le Contel, O., Retino, A., Mirioni, L., Huang, S. Y., Gershman, D. J., Ergun, R. E., Wilder, F. D., Goodrich, K. A., Ahmadi, N., Yordanova, E., Vaivads, Andris, Turner, D. L., Khotyaintsev, Yu. V., Graham, D. B., Lindqvist, Per-Arne, Chasapis, A., Burch, J. L., Torbert, R. B., Russell, C. T., Magnes, W., Strangeway, R. J., Plaschke, F., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Lavraud, B., Fuselier, S. A., and Cohen, I. J.

Abstract

The Earth's magnetosheath, which is characterized by highly turbulent fluctuations, is usually divided into two regions of different properties as a function of the angle between the interplanetary magnetic field and the shock normal. In this study, we make use of high-time resolution instruments on board the Magnetospheric MultiScale spacecraft to determine and compare the properties of subsolar magnetosheath turbulence in both regions, i. e., downstream of the quasi-parallel and quasi-perpendicular bow shocks. In particular, we take advantage of the unprecedented temporal resolution of the Fast Plasma Investigation instrument to show the density fluctuations down to sub-ion scales for the first time. We show that the nature of turbulence is highly compressible down to electron scales, particularly in the quasi-parallel magnetosheath. In this region, the magnetic turbulence also shows an inertial (Kolmogorov-like) range, indicating that the fluctuations are not formed locally, in contrast with the quasi-perpendicular magnetosheath. We also show that the electromagnetic turbulence is dominated by electric fluctuations at sub-ion scales (f > 1Hz) and that magnetic and electric spectra steepen at the largest-electron scale. The latter indicates a change in the nature of turbulence at electron scales. Finally, we show that the electric fluctuations around the electron gyrofrequency are mostly parallel in the quasi-perpendicular magnetosheath, where intense whistlers are observed. This result suggests that energy dissipation, plasma heating, and acceleration might be driven by intense electrostatic parallel structures/waves, which can be linked to whistler waves., QC 20180619

Published

2018

18. Intense Electric Fields and Electron-Scale Substructure Within Magnetotail Flux Ropes as Revealed by the Magnetospheric Multiscale Mission

Author

Stawarz, J. E., Eastwood, J. P., Genestreti, K. J., Nakamura, R., Ergun, R. E., Burgess, D., Burch, J. L., Fuselier, S. A., Gershman, D. J., Giles, B. L., Le Contel, O., Lindqvist, Per-Arne, Russell, C. T., Torbert, R. B., Stawarz, J. E., Eastwood, J. P., Genestreti, K. J., Nakamura, R., Ergun, R. E., Burgess, D., Burch, J. L., Fuselier, S. A., Gershman, D. J., Giles, B. L., Le Contel, O., Lindqvist, Per-Arne, Russell, C. T., and Torbert, R. B.

Abstract

Three flux ropes associated with near-Earth magnetotail reconnection are analyzed using Magnetospheric Multiscale observations. The flux ropes are Earthward propagating with sizes from similar to 3 to 11 ion inertial lengths. Significantly different axial orientations are observed, suggesting spatiotemporal variability in the reconnection and/or flux rope dynamics. An electron-scale vortex, associated with one of the most intense electric fields (E) in the event, is observed within one of the flux ropes. This E is predominantly perpendicular to the magnetic field (B); the electron vortex is frozen-in with E x B drifting electrons carrying perpendicular current and causing a small-scale magnetic enhancement. The vortex is similar to 16 electron gyroradii in size perpendicular to B and potentially elongated parallel to B. The need to decouple the frozen-in vortical motion from the surrounding plasma implies a parallel E at the structure's ends. The formation of frozen-in electron vortices within reconnection-generated flux ropes may have implications for particle acceleration. Plain LanguageSummary The release of magnetic energy into particle motion through magnetic reconnection is a key driver of dynamics in the Earth's magnetosphere and other space plasmas. In order to understand how the released magnetic energy is distributed and ultimately heats the particles, a detailed examination of the structures formed by magnetic reconnection is necessary. One common structure produced by reconnection is a twisted magnetic field known as a flux rope. We use new data from the National Aeronautics and Space Administration's Magnetospheric Multiscale satellites to examine both the large-and small-scale properties of three flux ropes associated with a single reconnection event. The results reveal the intrinsic three-dimensional nature of the overall reconnection event, which may stem either from variability at the reconnection site and/or the subsequent dynamics of the structure, QC 20181015

Published

2018

19. Electron magnetic reconnection without ion coupling in Earth's turbulent magnetosheath

Author

Phan, T. D., Eastwood, J. P., Shay, M. A., Drake, J. F., Sonnerup, B. U. O., Fujimoto, M., Cassak, P. A., Oieroset, M., Burch, J. L., Torbert, R. B., Rager, A. C., Dorelli, J. C., Gershman, D. J., Pollock, C., Pyakurel, P. S., Haggerty, C. C., Khotyaintsev, Y., Lavraud, B., Saito, Y., Oka, M., Ergun, R. E., Retino, A., Le Contel, O., Argall, M. R., Giles, B. L., Moore, T. E., Wilder, F. D., Strangeway, R. J., Russell, C. T., Lindqvist, Per-Arne, Magnes, W., Phan, T. D., Eastwood, J. P., Shay, M. A., Drake, J. F., Sonnerup, B. U. O., Fujimoto, M., Cassak, P. A., Oieroset, M., Burch, J. L., Torbert, R. B., Rager, A. C., Dorelli, J. C., Gershman, D. J., Pollock, C., Pyakurel, P. S., Haggerty, C. C., Khotyaintsev, Y., Lavraud, B., Saito, Y., Oka, M., Ergun, R. E., Retino, A., Le Contel, O., Argall, M. R., Giles, B. L., Moore, T. E., Wilder, F. D., Strangeway, R. J., Russell, C. T., Lindqvist, Per-Arne, and Magnes, W.

Abstract

Magnetic reconnection in current sheets is a magnetic-to-particle energy conversion process that is fundamental to many space and laboratory plasma systems. In the standard model of reconnection, this process occurs in a minuscule electron-scale diffusion region(1,2). On larger scales, ions couple to the newly reconnected magnetic-field lines and are ejected away from the diffusion region in the form of bi-directional ion jets at the ion Alfven speed(3-5). Much of the energy conversion occurs in spatially extended ion exhausts downstream of the diffusion region(6). In turbulent plasmas, which contain a large number of small-scale current sheets, reconnection has long been suggested to have a major role in the dissipation of turbulent energy at kinetic scales(7-11). However, evidence for reconnection plasma jetting in small-scale turbulent plasmas has so far been lacking. Here we report observations made in Earth's turbulent magnetosheath region (downstream of the bow shock) of an electron-scale current sheet in which diverging bi-directional super-ion-Alfvenic electron jets, parallel electric fields and enhanced magnetic-to-particle energy conversion were detected. Contrary to the standard model of reconnection, the thin reconnecting current sheet was not embedded in a wider ion-scale current layer and no ion jets were detected. Observations of this and other similar, but unidirectional, electron jet events without signatures of ion reconnection reveal a form of reconnection that can drive turbulent energy transfer and dissipation in electron-scale current sheets without ion coupling., QC 20180529

Published

2018

20. Magnetospheric Multiscale Observations of an Ion Diffusion Region With Large Guide Field at the Magnetopause : Current System, Electron Heating, and Plasma Waves

Author

Zhou, M., Berchem, J., Walker, R. J., El-Alaoui, M., Goldstein, M. L., Lapenta, G., Deng, X., Li, J., Le Contel, O., Graham, D. B., Lavraud, B., Paterson, W. R., Giles, B. L., Burch, J. L., Torbert, R. B., Russell, C. T., Strangeway, R. J., Zhao, C., Ergun, R. E., Lindqvist, Per-Arne, Marklund, Göran, Zhou, M., Berchem, J., Walker, R. J., El-Alaoui, M., Goldstein, M. L., Lapenta, G., Deng, X., Li, J., Le Contel, O., Graham, D. B., Lavraud, B., Paterson, W. R., Giles, B. L., Burch, J. L., Torbert, R. B., Russell, C. T., Strangeway, R. J., Zhao, C., Ergun, R. E., Lindqvist, Per-Arne, and Marklund, Göran

Abstract

We report Magnetospheric Multiscale (MMS) observations of a reconnecting current sheet in the presence of a weak density asymmetry with large guide field at the dayside magnetopause. An ion diffusion region (IDR) was detected associated with this current sheet. Parallel current dominated over the perpendicular current in the IDR, as found in previous studies of component reconnection. Electrons were preferentially heated parallel to the magnetic field within the IDR. The heating was manifested as a flattop distribution below 400eV. Two types of electromagnetic electron whistler waves were observed within the regions where electrons were heated. One type of whistler wave was associated with nonlinear structures in E-|| with amplitudes up to 20mV/m. The other type was not associated with any structures in E-||. Poynting fluxes of these two types of whistler waves were directed away from the X-line. We suggest that the nonlinear evolution of the oblique whistler waves gave rise to the solitary structures in E-||. There was a perpendicular super-Alfvenic outflow jet that was carried by magnetized electrons. Intense electrostatic lower hybrid drift waves were localized in the current sheet center and were probably driven by the super-Alfvenic electron jet, the velocity of which was approximately equal to the diamagnetic drift of demagnetized ions. Our observations suggest that the guide field significantly modified the structures (Hall electromagnetic fields and current system) and wave properties in the IDR., QC 20180518

Published

2018

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

Author

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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Fennell, J. F., 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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., and Fennell, J. F.

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.

Published

2018

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

Author

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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Fennell, J. F., 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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., and Fennell, J. F.

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.

Published

2018

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

Author

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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Fennell, J. F., 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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., and Fennell, J. F.

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.

Published

2018

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

Author

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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Fennell, J. F., 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, Daniel B., Argall, M. R., Fischer, D., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Ahmadi, N., Burch, J. L., Torbert, R. B., Needell, G., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., and Fennell, J. F.

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.

Published

2018

25. MMS Observation of Magnetic Reconnection in the Turbulent Magnetosheath

Author

Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., Saito, Y., Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., and Saito, Y.

Abstract

In this paper we use the full armament of the MMS (Magnetospheric Multiscale) spacecraft to study magnetic reconnection in the turbulent magnetosheath downstream of a quasi-parallel bow shock. Contrarily to the magnetopause and magnetotail cases, only a few observations of reconnection in the magnetosheath have been reported. The case study in this paper presents, for the first time, both fluid-scale and kinetic-scale signatures of an ongoing reconnection in the turbulent magnetosheath. The spacecraft are crossing the reconnection inflow and outflow regions and the ion diffusion region (IDR). Inside the reconnection outflows D shape ion distributions are observed. Inside the IDR mixing of ion populations, crescent-like velocity distributions and ion accelerations are observed. One of the spacecraft skims the outer region of the electron diffusion region, where parallel electric fields, energy dissipation/conversion, electron pressure tensor agyrotropy, electron temperature anisotropy, and electron accelerations are observed. Some of the difficulties of the observations of magnetic reconnection in turbulent plasma are also outlined.

Published

2017

26. Examining Coherency Scales, Substructure, and Propagation of Whistler Mode Chorus Elements With Magnetospheric Multiscale (MMS)

Author

Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., Santolik, O., Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., and Santolik, O.

Abstract

Whistler mode chorus waves are a naturally occurring electromagnetic emission observed in Earth's magnetosphere. Here, for the first time, data from NASA's Magnetospheric Multiscale (MMS) mission were used to analyze chorus waves in detail, including the calculation of chorus wave normal vectors, k. A case study was examined from a period of substorm activity around the time of a conjunction between the MMS constellation and NASA's Van Allen Probes mission on 07 April 2016. Chorus wave activity was simultaneously observed by all six spacecraft over a broad range of L shells (5.5 < L < 8.5), magnetic local time (06: 00 < MLT < 09: 00), and magnetic latitude (-32 degrees < MLAT < -15 degrees), implying a large chorus active region. Eight chorus elements and their substructure were analyzed in detail with MMS. These chorus elements were all lower band and rising tone emissions, right-handed and nearly circularly polarized, and propagating away from the magnetic equator when they were observed at MMS (MLAT similar to-31 degrees). Most of the elements had "hook"-like signatures on their wave power spectra, characterized by enhanced wave power at flat or falling frequency following the peak, and all the elements exhibited complex and well-organized substructure observed consistently at all four MMS spacecraft at separations up to 70 km (60 km perpendicular and 38 km parallel to the background magnetic field). The waveforms in field-aligned coordinates also demonstrated that these waves were all phase coherent, allowing for the direct calculation of k. Error estimates on calculated k revealed that the plane wave approximation was valid for six of the eight elements and most of the subelements. The wave normal vectors were within 20-30 degrees from the direction antiparallel to the background field for all elements and changed from subelement to subelement through at least two of the eight elements. The azimuthal angle of k in the perpendicular plane was o

Published

2017

27. MMS Observations of Reconnection at Dayside Magnetopause Crossings During Transitions of the Solar Wind to Sub-Alfvenic Flow

Author

Farrugia, C. J., Lugaz, N., Alm, L., Vasquez, B., Argall, M. R., Kucharek, H., Matsui, H., Torbert, R. B., Lavraud, B., Le Contel, O., Cohen, I. J., Burch, J. L., Russell, C. T., Strangeway, R. J., Shuster, J., Dorelli, J. C., Eastwood, J. P., Ergun, R. E., Fuselier, S. A., Gershman, D. J., Giles, B. L., Khotyaintsev, Yuri V., Lindqvist, P. A., Marklund, G. T., Paulson, K. W., Petrinec, S. M., Phan, T. D., Pollock, C. J., Farrugia, C. J., Lugaz, N., Alm, L., Vasquez, B., Argall, M. R., Kucharek, H., Matsui, H., Torbert, R. B., Lavraud, B., Le Contel, O., Cohen, I. J., Burch, J. L., Russell, C. T., Strangeway, R. J., Shuster, J., Dorelli, J. C., Eastwood, J. P., Ergun, R. E., Fuselier, S. A., Gershman, D. J., Giles, B. L., Khotyaintsev, Yuri V., Lindqvist, P. A., Marklund, G. T., Paulson, K. W., Petrinec, S. M., Phan, T. D., and Pollock, C. J.

Abstract

We present MMS observations during two dayside magnetopause crossings under hitherto unexamined conditions: (i) when the bow shock is weakening and the solar wind transitioning to sub-Alfvenic flow and (ii) when it is reforming. Interplanetary conditions consist of a magnetic cloud with (i) a strong B (similar to 20 nT) pointing south and (ii) a density profile with episodic decreases to values of similar to 0.3 cm(-3) followed by moderate recovery. During the crossings the magnetosheath magnetic field is stronger than the magnetosphere field by a factor of similar to 2.2. As a result, during the outbound crossing through the ion diffusion region, MMS observed an inversion of the relative positions of the X and stagnation (S) lines from that typically the case: the S line was closer to the magnetosheath side. The S line appears in the form of a slow expansion fan near which most of the energy dissipation is taking place. While in the magnetosphere between the crossings, MMS observed strong field and flow perturbations, which we argue to be due to kinetic Alfven waves. During the reconnection interval, whistler mode waves generated by an electron temperature anisotropy (T-e perpendicular to > T-e parallel to) were observed. Another aim of the paper is to distinguish bow shock-induced field and flow perturbations from reconnection-related signatures. The high-resolution MMS data together with 2-D hybrid simulations of bow shock dynamics helped us to distinguish between the two sources. We show examples of bow shock-related effects (such as heating) and reconnection effects such as accelerated flows satisfying the Walen relation.

Published

2017

28. Lower Hybrid Drift Waves and Electromagnetic Electron Space-Phase Holes Associated With Dipolarization Fronts and Field-Aligned Currents Observed by the Magnetospheric Multiscale Mission During a Substorm

Author

Le Contel, O., Nakamura, R., Breuillard, H., Argall, M. R., Graham, Daniel B., Fischer, D., Retino, A., Berthomier, M., Pottelette, R., Mirioni, L., Chust, T., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Norgren, Cecilia, Ergun, R. E., Goodrich, K. A., Burch, J. L., Torbert, R. B., Needell, J., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H. Y., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Turner, D. L., Fennell, J. F., Leonard, T., Jaynes, A. N., Le Contel, O., Nakamura, R., Breuillard, H., Argall, M. R., Graham, Daniel B., Fischer, D., Retino, A., Berthomier, M., Pottelette, R., Mirioni, L., Chust, T., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A, Khotyaintsev, Yuri V., Norgren, Cecilia, Ergun, R. E., Goodrich, K. A., Burch, J. L., Torbert, R. B., Needell, J., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H. Y., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Saito, Y., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Turner, D. L., Fennell, J. F., Leonard, T., and Jaynes, A. N.

Abstract

We analyze two ion scale dipolarization fronts associated with field-aligned currents detected by the Magnetospheric Multiscale mission during a large substorm on 10 August 2016. The first event corresponds to a fast dawnward flow with an antiparallel current and could be generated by the wake of a previous fast earthward flow. It is associated with intense lower hybrid drift waves detected at the front and propagating dawnward with a perpendicular phase speed close to the electric drift and the ion thermal velocity. The second event corresponds to a flow reversal: from southwward/dawnward to northward/duskward associated with a parallel current consistent with a brief expansion of the plasma sheet before the front crossing and with a smaller lower hybrid drift wave activity. Electromagnetic electron phase-space holes are detected near these low-frequency drift waves during both events. The drift waves could accelerate electrons parallel to the magnetic field and produce the parallel electron drift needed to generate the electron holes. Yet we cannot rule out the possibility that the drift waves are produced by the antiparallel current associated with the fast flows, leaving the source for the electron holes unexplained.

Published

2017

29. MMS Observation of Magnetic Reconnection in the Turbulent Magnetosheath

Author

Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., Saito, Y., Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., and Saito, Y.

Abstract

In this paper we use the full armament of the MMS (Magnetospheric Multiscale) spacecraft to study magnetic reconnection in the turbulent magnetosheath downstream of a quasi-parallel bow shock. Contrarily to the magnetopause and magnetotail cases, only a few observations of reconnection in the magnetosheath have been reported. The case study in this paper presents, for the first time, both fluid-scale and kinetic-scale signatures of an ongoing reconnection in the turbulent magnetosheath. The spacecraft are crossing the reconnection inflow and outflow regions and the ion diffusion region (IDR). Inside the reconnection outflows D shape ion distributions are observed. Inside the IDR mixing of ion populations, crescent-like velocity distributions and ion accelerations are observed. One of the spacecraft skims the outer region of the electron diffusion region, where parallel electric fields, energy dissipation/conversion, electron pressure tensor agyrotropy, electron temperature anisotropy, and electron accelerations are observed. Some of the difficulties of the observations of magnetic reconnection in turbulent plasma are also outlined.

Published

2017

30. MMS Observation of Magnetic Reconnection in the Turbulent Magnetosheath

Author

Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., Saito, Y., Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., and Saito, Y.

Abstract

In this paper we use the full armament of the MMS (Magnetospheric Multiscale) spacecraft to study magnetic reconnection in the turbulent magnetosheath downstream of a quasi-parallel bow shock. Contrarily to the magnetopause and magnetotail cases, only a few observations of reconnection in the magnetosheath have been reported. The case study in this paper presents, for the first time, both fluid-scale and kinetic-scale signatures of an ongoing reconnection in the turbulent magnetosheath. The spacecraft are crossing the reconnection inflow and outflow regions and the ion diffusion region (IDR). Inside the reconnection outflows D shape ion distributions are observed. Inside the IDR mixing of ion populations, crescent-like velocity distributions and ion accelerations are observed. One of the spacecraft skims the outer region of the electron diffusion region, where parallel electric fields, energy dissipation/conversion, electron pressure tensor agyrotropy, electron temperature anisotropy, and electron accelerations are observed. Some of the difficulties of the observations of magnetic reconnection in turbulent plasma are also outlined.

Published

2017

31. Examining Coherency Scales, Substructure, and Propagation of Whistler Mode Chorus Elements With Magnetospheric Multiscale (MMS)

Author

Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., Santolik, O., Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., and Santolik, O.

Abstract

Whistler mode chorus waves are a naturally occurring electromagnetic emission observed in Earth's magnetosphere. Here, for the first time, data from NASA's Magnetospheric Multiscale (MMS) mission were used to analyze chorus waves in detail, including the calculation of chorus wave normal vectors, k. A case study was examined from a period of substorm activity around the time of a conjunction between the MMS constellation and NASA's Van Allen Probes mission on 07 April 2016. Chorus wave activity was simultaneously observed by all six spacecraft over a broad range of L shells (5.5 < L < 8.5), magnetic local time (06: 00 < MLT < 09: 00), and magnetic latitude (-32 degrees < MLAT < -15 degrees), implying a large chorus active region. Eight chorus elements and their substructure were analyzed in detail with MMS. These chorus elements were all lower band and rising tone emissions, right-handed and nearly circularly polarized, and propagating away from the magnetic equator when they were observed at MMS (MLAT similar to-31 degrees). Most of the elements had "hook"-like signatures on their wave power spectra, characterized by enhanced wave power at flat or falling frequency following the peak, and all the elements exhibited complex and well-organized substructure observed consistently at all four MMS spacecraft at separations up to 70 km (60 km perpendicular and 38 km parallel to the background magnetic field). The waveforms in field-aligned coordinates also demonstrated that these waves were all phase coherent, allowing for the direct calculation of k. Error estimates on calculated k revealed that the plane wave approximation was valid for six of the eight elements and most of the subelements. The wave normal vectors were within 20-30 degrees from the direction antiparallel to the background field for all elements and changed from subelement to subelement through at least two of the eight elements. The azimuthal angle of k in the perpendicular plane was o

Published

2017

32. Examining Coherency Scales, Substructure, and Propagation of Whistler Mode Chorus Elements With Magnetospheric Multiscale (MMS)

Author

Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., Santolik, O., Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., and Santolik, O.

Abstract

Whistler mode chorus waves are a naturally occurring electromagnetic emission observed in Earth's magnetosphere. Here, for the first time, data from NASA's Magnetospheric Multiscale (MMS) mission were used to analyze chorus waves in detail, including the calculation of chorus wave normal vectors, k. A case study was examined from a period of substorm activity around the time of a conjunction between the MMS constellation and NASA's Van Allen Probes mission on 07 April 2016. Chorus wave activity was simultaneously observed by all six spacecraft over a broad range of L shells (5.5 < L < 8.5), magnetic local time (06: 00 < MLT < 09: 00), and magnetic latitude (-32 degrees < MLAT < -15 degrees), implying a large chorus active region. Eight chorus elements and their substructure were analyzed in detail with MMS. These chorus elements were all lower band and rising tone emissions, right-handed and nearly circularly polarized, and propagating away from the magnetic equator when they were observed at MMS (MLAT similar to-31 degrees). Most of the elements had "hook"-like signatures on their wave power spectra, characterized by enhanced wave power at flat or falling frequency following the peak, and all the elements exhibited complex and well-organized substructure observed consistently at all four MMS spacecraft at separations up to 70 km (60 km perpendicular and 38 km parallel to the background magnetic field). The waveforms in field-aligned coordinates also demonstrated that these waves were all phase coherent, allowing for the direct calculation of k. Error estimates on calculated k revealed that the plane wave approximation was valid for six of the eight elements and most of the subelements. The wave normal vectors were within 20-30 degrees from the direction antiparallel to the background field for all elements and changed from subelement to subelement through at least two of the eight elements. The azimuthal angle of k in the perpendicular plane was o

Published

2017

33. Magnetospheric Multiscale Observations of Electron Vortex Magnetic Hole in the Turbulent Magnetosheath Plasma

Author

Huang, S. Y., Sahraoui, F., Yuan, Z. G., He, J. S., Zhao, J. S., Le Contel, O., Deng, X. H., Zhou, M., Fu, H. S., Shi, Q. Q., Lavraud, B., Pang, Y., Yang, J., Wang, D. D., Li, H. M., Yu, X. D., Pollock, C. J., Giles, B. L., Torbert, R. B., Russell, C. T., Goodrich, K. A., Gershman, D. J., Moore, T. E., Ergun, R. E., Khotyaintsev, Y. V., Lindqvist, P. -A, Strangeway, R. J., Magnes, W., Bromund, K., Leinweber, H., Plaschke, F., Anderson, B. J., Burch, J. L., Huang, S. Y., Sahraoui, F., Yuan, Z. G., He, J. S., Zhao, J. S., Le Contel, O., Deng, X. H., Zhou, M., Fu, H. S., Shi, Q. Q., Lavraud, B., Pang, Y., Yang, J., Wang, D. D., Li, H. M., Yu, X. D., Pollock, C. J., Giles, B. L., Torbert, R. B., Russell, C. T., Goodrich, K. A., Gershman, D. J., Moore, T. E., Ergun, R. E., Khotyaintsev, Y. V., Lindqvist, P. -A, Strangeway, R. J., Magnes, W., Bromund, K., Leinweber, H., Plaschke, F., Anderson, B. J., and Burch, J. L.

Abstract

We report on the observations of an electron vortex magnetic hole corresponding to a new type of coherent structure in the turbulent magnetosheath plasma using the Magnetospheric Multiscale mission data. The magnetic hole is characterized by a magnetic depression, a density peak, a total electron temperature increase (with a parallel temperature decrease but a perpendicular temperature increase), and strong currents carried by the electrons. The current has a dip in the core region and a peak in the outer region of the magnetic hole. The estimated size of the magnetic hole is about 0.23 rho(i) (similar to 30 rho(e)) in the quasi-circular cross-section perpendicular to its axis, where rho(i) and rho(e) are respectively the proton and electron gyroradius. There are no clear enhancements seen in high-energy electron fluxes. However, there is an enhancement in the perpendicular electron fluxes at 90 degrees pitch angle inside the magnetic hole, implying that the electrons are trapped within it. The variations of the electron velocity components V-em and V-en suggest that an electron vortex is formed by trapping electrons inside the magnetic hole in the cross-section in the M-N plane. These observations demonstrate the existence of a new type of coherent structures behaving as an electron vortex magnetic hole in turbulent space plasmas as predicted by recent kinetic simulations.

Published

2017

34. Drift waves, intense parallel electric fields, and turbulence associated with asymmetric magnetic reconnection at the magnetopause

Author

Ergun, R. E., Chen, L. -J, Wilder, F. D., Ahmadi, N., Eriksson, S., Usanova, M. E., Goodrich, K. A., Holmes, J. C., Sturner, A. P., Malaspina, D. M., Newman, D. L., Torbert, R. B., Argall, M. R., Lindqvist, P. -A, Burch, J. L., Webster, J. M., Drake, J. F., Price, L., Cassak, P. A., Swisdak, M., Shay, M. A., Graham, Daniel, Strangeway, R. J., Russell, C. T., Giles, B. L., Dorelli, J. C., Gershman, D., Avanov, L., Hesse, M., Lavraud, B., Le Contel, O., Retino, A., Phan, T. D., Goldman, M. V., Stawarz, J. E., Schwartz, S. J., Eastwood, J. P., Hwang, K. -J, Nakamura, R., Wang, S., Ergun, R. E., Chen, L. -J, Wilder, F. D., Ahmadi, N., Eriksson, S., Usanova, M. E., Goodrich, K. A., Holmes, J. C., Sturner, A. P., Malaspina, D. M., Newman, D. L., Torbert, R. B., Argall, M. R., Lindqvist, P. -A, Burch, J. L., Webster, J. M., Drake, J. F., Price, L., Cassak, P. A., Swisdak, M., Shay, M. A., Graham, Daniel, Strangeway, R. J., Russell, C. T., Giles, B. L., Dorelli, J. C., Gershman, D., Avanov, L., Hesse, M., Lavraud, B., Le Contel, O., Retino, A., Phan, T. D., Goldman, M. V., Stawarz, J. E., Schwartz, S. J., Eastwood, J. P., Hwang, K. -J, Nakamura, R., and Wang, S.

Abstract

Observations of magnetic reconnection at Earth's magnetopause often display asymmetric structures that are accompanied by strong magnetic field (B) fluctuations and large-amplitude parallel electric fields (E-||). The B turbulence is most intense at frequencies above the ion cyclotron frequency and below the lower hybrid frequency. The B fluctuations are consistent with a thin, oscillating current sheet that is corrugated along the electron flow direction (along the X line), which is a type of electromagnetic drift wave. Near the X line, electron flow is primarily due to a Hall electric field, which diverts ion flow in asymmetric reconnection and accompanies the instability. Importantly, the drift waves appear to drive strong parallel currents which, in turn, generate large-amplitude (similar to 100mV/m) E-|| in the form of nonlinear waves and structures. These observations suggest that turbulence may be common in asymmetric reconnection, penetrate into the electron diffusion region, and possibly influence the magnetic reconnection process.

Published

2017

35. The nonlinear behavior of whistler waves at the reconnecting dayside magnetopause as observed by the Magnetospheric Multiscale mission : A case study

Author

Wilder, F. D., Ergun, R. E., Newman, D. L., Goodrich, K. A., Trattner, K. J., Goldman, M. V., Eriksson, S., Jaynes, A. N., Leonard, T., Malaspina, D. M., Ahmadi, N., Schwartz, S. J., Burch, J. L., Torbert, R. B., Argall, M. R., Giles, B. L., Phan, T. D., Le Contel, O., Graham, D. B., Khotyaintsev, Yuri V., Strangeway, R. J., Russell, C. T., Magnes, W., Plaschke, F., Lindqvist, P. -A, Wilder, F. D., Ergun, R. E., Newman, D. L., Goodrich, K. A., Trattner, K. J., Goldman, M. V., Eriksson, S., Jaynes, A. N., Leonard, T., Malaspina, D. M., Ahmadi, N., Schwartz, S. J., Burch, J. L., Torbert, R. B., Argall, M. R., Giles, B. L., Phan, T. D., Le Contel, O., Graham, D. B., Khotyaintsev, Yuri V., Strangeway, R. J., Russell, C. T., Magnes, W., Plaschke, F., and Lindqvist, P. -A

Abstract

We show observations of whistler mode waves in both the low-latitude boundary layer (LLBL) and on closed magnetospheric field lines during a crossing of the dayside reconnecting magnetopause by the Magnetospheric Multiscale (MMS) mission on 11 October 2015. The whistlers in the LLBL were on the electron edge of the magnetospheric separatrix and exhibited high propagation angles with respect to the background field, approaching 40 degrees, with bursty and nonlinear parallel electric field signatures. The whistlers in the closed magnetosphere had Poynting flux that was more field aligned. Comparing the reduced electron distributions for each event, the magnetospheric whistlers appear to be consistent with anisotropy-driven waves, while the distribution in the LLBL case includes anisotropic backward resonant electrons and a forward resonant beam at near half the electron-Alfven speed. Results are compared with the previously published observations by MMS on 19 September 2015 of LLBL whistler waves. The observations suggest that whistlers in the LLBL can be both beam and anisotropy driven, and the relative contribution of each might depend on the distance from the X line.

Published

2017

36. MMS Observation of Magnetic Reconnection in the Turbulent Magnetosheath

Author

Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., Saito, Y., Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., and Saito, Y.

Abstract

In this paper we use the full armament of the MMS (Magnetospheric Multiscale) spacecraft to study magnetic reconnection in the turbulent magnetosheath downstream of a quasi-parallel bow shock. Contrarily to the magnetopause and magnetotail cases, only a few observations of reconnection in the magnetosheath have been reported. The case study in this paper presents, for the first time, both fluid-scale and kinetic-scale signatures of an ongoing reconnection in the turbulent magnetosheath. The spacecraft are crossing the reconnection inflow and outflow regions and the ion diffusion region (IDR). Inside the reconnection outflows D shape ion distributions are observed. Inside the IDR mixing of ion populations, crescent-like velocity distributions and ion accelerations are observed. One of the spacecraft skims the outer region of the electron diffusion region, where parallel electric fields, energy dissipation/conversion, electron pressure tensor agyrotropy, electron temperature anisotropy, and electron accelerations are observed. Some of the difficulties of the observations of magnetic reconnection in turbulent plasma are also outlined.

Published

2017

37. Examining Coherency Scales, Substructure, and Propagation of Whistler Mode Chorus Elements With Magnetospheric Multiscale (MMS)

Author

Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., Santolik, O., Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., and Santolik, O.

Abstract

Whistler mode chorus waves are a naturally occurring electromagnetic emission observed in Earth's magnetosphere. Here, for the first time, data from NASA's Magnetospheric Multiscale (MMS) mission were used to analyze chorus waves in detail, including the calculation of chorus wave normal vectors, k. A case study was examined from a period of substorm activity around the time of a conjunction between the MMS constellation and NASA's Van Allen Probes mission on 07 April 2016. Chorus wave activity was simultaneously observed by all six spacecraft over a broad range of L shells (5.5 < L < 8.5), magnetic local time (06: 00 < MLT < 09: 00), and magnetic latitude (-32 degrees < MLAT < -15 degrees), implying a large chorus active region. Eight chorus elements and their substructure were analyzed in detail with MMS. These chorus elements were all lower band and rising tone emissions, right-handed and nearly circularly polarized, and propagating away from the magnetic equator when they were observed at MMS (MLAT similar to-31 degrees). Most of the elements had "hook"-like signatures on their wave power spectra, characterized by enhanced wave power at flat or falling frequency following the peak, and all the elements exhibited complex and well-organized substructure observed consistently at all four MMS spacecraft at separations up to 70 km (60 km perpendicular and 38 km parallel to the background magnetic field). The waveforms in field-aligned coordinates also demonstrated that these waves were all phase coherent, allowing for the direct calculation of k. Error estimates on calculated k revealed that the plane wave approximation was valid for six of the eight elements and most of the subelements. The wave normal vectors were within 20-30 degrees from the direction antiparallel to the background field for all elements and changed from subelement to subelement through at least two of the eight elements. The azimuthal angle of k in the perpendicular plane was o

Published

2017

38. MMS Observation of Magnetic Reconnection in the Turbulent Magnetosheath

Author

Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., Saito, Y., Voros, Z., Yordanova, Emiliya, Varsani, A., Genestreti, K. J., Khotyaintsev, Yuri V., Li, Wenya, Graham, Daniel B., Norgren, Cecilia, Nakamura, R., Narita, Y., Plaschke, F., Magnes, W., Baumjohann, W., Fischer, D., Vaivads, Andris, Eriksson, Elin, Lindqvist, P. -A, Marklund, G., Ergun, R. E., Leitner, M., Leubner, M. P., Strangeway, R. J., Le Contel, O., Pollock, C., Giles, B. J., Torbert, R. B., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., and Saito, Y.

Abstract

In this paper we use the full armament of the MMS (Magnetospheric Multiscale) spacecraft to study magnetic reconnection in the turbulent magnetosheath downstream of a quasi-parallel bow shock. Contrarily to the magnetopause and magnetotail cases, only a few observations of reconnection in the magnetosheath have been reported. The case study in this paper presents, for the first time, both fluid-scale and kinetic-scale signatures of an ongoing reconnection in the turbulent magnetosheath. The spacecraft are crossing the reconnection inflow and outflow regions and the ion diffusion region (IDR). Inside the reconnection outflows D shape ion distributions are observed. Inside the IDR mixing of ion populations, crescent-like velocity distributions and ion accelerations are observed. One of the spacecraft skims the outer region of the electron diffusion region, where parallel electric fields, energy dissipation/conversion, electron pressure tensor agyrotropy, electron temperature anisotropy, and electron accelerations are observed. Some of the difficulties of the observations of magnetic reconnection in turbulent plasma are also outlined.

Published

2017

39. Examining Coherency Scales, Substructure, and Propagation of Whistler Mode Chorus Elements With Magnetospheric Multiscale (MMS)

Author

Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., Santolik, O., Turner, D. L., Lee, J. H., Claudepierre, S. G., Fennell, J. F., Blake, J. B., Jaynes, A. N., Leonard, T., Wilder, F. D., Ergun, R. E., Baker, D. N., Cohen, I. J., Mauk, B. H., Strangeway, R. J., Hartley, D. P., Kletzing, C. A., Breuillard, H., Le Contel, O., Khotyaintsev, Yuri V., Torbert, R. B., Allen, R. C., Burch, J. L., and Santolik, O.

Abstract

Whistler mode chorus waves are a naturally occurring electromagnetic emission observed in Earth's magnetosphere. Here, for the first time, data from NASA's Magnetospheric Multiscale (MMS) mission were used to analyze chorus waves in detail, including the calculation of chorus wave normal vectors, k. A case study was examined from a period of substorm activity around the time of a conjunction between the MMS constellation and NASA's Van Allen Probes mission on 07 April 2016. Chorus wave activity was simultaneously observed by all six spacecraft over a broad range of L shells (5.5 < L < 8.5), magnetic local time (06: 00 < MLT < 09: 00), and magnetic latitude (-32 degrees < MLAT < -15 degrees), implying a large chorus active region. Eight chorus elements and their substructure were analyzed in detail with MMS. These chorus elements were all lower band and rising tone emissions, right-handed and nearly circularly polarized, and propagating away from the magnetic equator when they were observed at MMS (MLAT similar to-31 degrees). Most of the elements had "hook"-like signatures on their wave power spectra, characterized by enhanced wave power at flat or falling frequency following the peak, and all the elements exhibited complex and well-organized substructure observed consistently at all four MMS spacecraft at separations up to 70 km (60 km perpendicular and 38 km parallel to the background magnetic field). The waveforms in field-aligned coordinates also demonstrated that these waves were all phase coherent, allowing for the direct calculation of k. Error estimates on calculated k revealed that the plane wave approximation was valid for six of the eight elements and most of the subelements. The wave normal vectors were within 20-30 degrees from the direction antiparallel to the background field for all elements and changed from subelement to subelement through at least two of the eight elements. The azimuthal angle of k in the perpendicular plane was o

Published

2017

40. Electron scale structures and magnetic reconnection signatures in the turbulent magnetosheath

Author

Yordanova, Emiliya, Voros, Z., Varsani, A., Graham, Daniel B., Norgren, Cecilia, Khotyaintsev, Yuri V., Vaivads, Andris, Eriksson, Elin, Nakamura, R., Lindqvist, P. -A, Marklund, G., Ergun, R. E., Magnes, W., Baumjohann, W., Fischer, D., Plaschke, F., Narita, Y., Russell, C. T., Strangeway, R. J., Le Contel, O., Pollock, C., Torbert, R. B., Giles, B. J., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., Saito, Y., Yordanova, Emiliya, Voros, Z., Varsani, A., Graham, Daniel B., Norgren, Cecilia, Khotyaintsev, Yuri V., Vaivads, Andris, Eriksson, Elin, Nakamura, R., Lindqvist, P. -A, Marklund, G., Ergun, R. E., Magnes, W., Baumjohann, W., Fischer, D., Plaschke, F., Narita, Y., Russell, C. T., Strangeway, R. J., Le Contel, O., Pollock, C., Torbert, R. B., Giles, B. J., Burch, J. L., Avanov, L. A., Dorelli, J. C., Gershman, D. J., Paterson, W. R., Lavraud, B., and Saito, Y.

Abstract

Collisionless space plasma turbulence can generate reconnecting thin current sheets as suggested by recent results of numerical magnetohydrodynamic simulations. The Magnetospheric Multiscale (MMS) mission provides the first serious opportunity to verify whether small ion-electron-scale reconnection, generated by turbulence, resembles the reconnection events frequently observed in the magnetotail or at the magnetopause. Here we investigate field and particle observations obtained by the MMS fleet in the turbulent terrestrial magnetosheath behind quasi-parallel bow shock geometry. We observe multiple small-scale current sheets during the event and present a detailed look of one of the detected structures. The emergence of thin current sheets can lead to electron scale structures. Within these structures, we see signatures of ion demagnetization, electron jets, electron heating, and agyrotropy suggesting that MMS spacecraft observe reconnection at these scales.

Published

2016

41. MMS observations of ion-scale magnetic island in the magnetosheath turbulent plasma

Author

Huang, S. Y., Sahraoui, F., Retino, A., Le Contel, O., Yuan, Z. G., Chasapis, A., Aunai, N., Breuillard, H., Deng, X. H., Zhou, M., Fu, H. S., Pang, Y., Wang, D. D., Torbert, R. B., Goodrich, K. A., Ergun, R. E., Khotyaintsev, Yuri V., Lindqvist, P. -A, Russell, C. T., Strangeway, R. J., Magnes, W., Bromund, K., Leinweber, H., Plaschke, F., Anderson, B. J., Pollock, C. J., Giles, B. L., Moore, T. E., Burch, J. L., Huang, S. Y., Sahraoui, F., Retino, A., Le Contel, O., Yuan, Z. G., Chasapis, A., Aunai, N., Breuillard, H., Deng, X. H., Zhou, M., Fu, H. S., Pang, Y., Wang, D. D., Torbert, R. B., Goodrich, K. A., Ergun, R. E., Khotyaintsev, Yuri V., Lindqvist, P. -A, Russell, C. T., Strangeway, R. J., Magnes, W., Bromund, K., Leinweber, H., Plaschke, F., Anderson, B. J., Pollock, C. J., Giles, B. L., Moore, T. E., and Burch, J. L.

Abstract

In this letter, first observations of ion-scale magnetic island from the Magnetospheric Multiscale mission in the magnetosheath turbulent plasma are presented. The magnetic island is characterized by bipolar variation of magnetic fields with magnetic field compression, strong core field, density depletion, and strong currents dominated by the parallel component to the local magnetic field. The estimated size of magnetic island is about 8 d(i), where d(i) is the ion inertial length. Distinct particle behaviors and wave activities inside and at the edges of the magnetic island are observed: parallel electron beam accompanied with electrostatic solitary waves and strong electromagnetic lower hybrid drift waves inside the magnetic island and bidirectional electron beams, whistler waves, weak electromagnetic lower hybrid drift waves, and strong broadband electrostatic noise at the edges of the magnetic island. Our observations demonstrate that highly dynamical, strong wave activities and electron-scale physics occur within ion-scale magnetic islands in the magnetosheath turbulent plasma.

Published

2016

42. Electron jet of asymmetric reconnection

Author

Khotyaintsev, Yuri V., Graham, D. B., Norgren, Cecilia, Eriksson, Elin, Li, Wenya, Johlander, Andreas, Vaivads, Andris, Andre, Mats, Pritchett, P. L., Retino, A., Phan, T. D., Ergun, R. E., Goodrich, K., Lindqvist, P. -A, Marklund, G. T., Le Contel, O., Plaschke, F., Magnes, W., Strangeway, R. J., Russell, C. T., Vaith, H., Argall, M. R., Kletzing, C. A., Nakamura, R., Torbert, R. B., Paterson, W. R., Gershman, D. J., Dorelli, J. C., Avanov, L. A., Lavraud, B., Saito, Y., Giles, B. L., Pollock, C. J., Turner, D. L., Blake, J. D., Fennell, J. F., Jaynes, A., Mauk, B. H., Burch, J. L., Khotyaintsev, Yuri V., Graham, D. B., Norgren, Cecilia, Eriksson, Elin, Li, Wenya, Johlander, Andreas, Vaivads, Andris, Andre, Mats, Pritchett, P. L., Retino, A., Phan, T. D., Ergun, R. E., Goodrich, K., Lindqvist, P. -A, Marklund, G. T., Le Contel, O., Plaschke, F., Magnes, W., Strangeway, R. J., Russell, C. T., Vaith, H., Argall, M. R., Kletzing, C. A., Nakamura, R., Torbert, R. B., Paterson, W. R., Gershman, D. J., Dorelli, J. C., Avanov, L. A., Lavraud, B., Saito, Y., Giles, B. L., Pollock, C. J., Turner, D. L., Blake, J. D., Fennell, J. F., Jaynes, A., Mauk, B. H., and Burch, J. L.

Abstract

We present Magnetospheric Multiscale observations of an electron-scale current sheet and electron outflow jet for asymmetric reconnection with guide field at the subsolar magnetopause. The electron jet observed within the reconnection region has an electron Mach number of 0.35 and is associated with electron agyrotropy. The jet is unstable to an electrostatic instability which generates intense waves with E-vertical bar amplitudes reaching up to 300mVm(-1) and potentials up to 20% of the electron thermal energy. We see evidence of interaction between the waves and the electron beam, leading to quick thermalization of the beam and stabilization of the instability. The wave phase speed is comparable to the ion thermal speed, suggesting that the instability is of Buneman type, and therefore introduces electron-ion drag and leads to braking of the electron flow. Our observations demonstrate that electrostatic turbulence plays an important role in the electron-scale physics of asymmetric reconnection.

Published

2016

43. Magnetospheric Multiscale observations of large-amplitude, parallel, electrostatic waves associated with magnetic reconnection at the magnetopause

Author

Ergun, R. E., Holmes, J. C., Goodrich, K. A., Wilder, F. D., Stawarz, J. E., Eriksson, S., Newman, D. L., Schwartz, S. J., Goldman, M. V., Sturner, A. P., Malaspina, D. M., Usanova, M. E., Torbert, R. B., Argall, M., Lindqvist, P-A, Khotyaintsev, Yuri, Burch, J. L., Strangeway, R. J., Russell, C. T., Pollock, C. J., Giles, B. L., Dorelli, J. J. C., Avanov, L., Hesse, M., Chen, L. J., Lavraud, B., Le Contel, O., Retino, A., Phan, T. D., Eastwood, J. P., Oieroset, M., Drake, J., Shay, M. A., Cassak, P. A., Nakamura, R., Zhou, M., Ashour-Abdalla, M., Andre, M., Ergun, R. E., Holmes, J. C., Goodrich, K. A., Wilder, F. D., Stawarz, J. E., Eriksson, S., Newman, D. L., Schwartz, S. J., Goldman, M. V., Sturner, A. P., Malaspina, D. M., Usanova, M. E., Torbert, R. B., Argall, M., Lindqvist, P-A, Khotyaintsev, Yuri, Burch, J. L., Strangeway, R. J., Russell, C. T., Pollock, C. J., Giles, B. L., Dorelli, J. J. C., Avanov, L., Hesse, M., Chen, L. J., Lavraud, B., Le Contel, O., Retino, A., Phan, T. D., Eastwood, J. P., Oieroset, M., Drake, J., Shay, M. A., Cassak, P. A., Nakamura, R., Zhou, M., Ashour-Abdalla, M., and Andre, M.

Abstract

We report observations from the Magnetospheric Multiscale satellites of large-amplitude, parallel, electrostatic waves associated with magnetic reconnection at the Earth's magnetopause. The observed waves have parallel electric fields (E-||) with amplitudes on the order of 100mV/m and display nonlinear characteristics that suggest a possible net E-||. These waves are observed within the ion diffusion region and adjacent to (within several electron skin depths) the electron diffusion region. They are in or near the magnetosphere side current layer. Simulation results support that the strong electrostatic linear and nonlinear wave activities appear to be driven by a two stream instability, which is a consequence of mixing cold (<10eV) plasma in the magnetosphere with warm (similar to 100eV) plasma from the magnetosheath on a freshly reconnected magnetic field line. The frequent observation of these waves suggests that cold plasma is often present near the magnetopause.

Published

2016

44. Multispacecraft analysis of dipolarization fronts and associated whistler wave emissions using MMS data

Author

Breuillard, H., Le Contel, O., Retino, A., Chasapis, A., Chust, T., Mirioni, L., Graham, Daniel B., Wilder, F. D., Cohen, I., Vaivads, Andris, Khotyaintsev, Yuri V., Lindqvist, P. -A, Marklund, G. T., Burch, J. L., Torbert, R. B., Ergun, R. E., Goodrich, K. A., Macri, J., Needell, J., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Plaschke, F., Fischer, D., Leinweber, H. K., Anderson, B. J., Le, G., Slavin, J. A., Kepko, E. L., Baumjohann, W., Mauk, B., Fuselier, S. A., Nakamura, R., Breuillard, H., Le Contel, O., Retino, A., Chasapis, A., Chust, T., Mirioni, L., Graham, Daniel B., Wilder, F. D., Cohen, I., Vaivads, Andris, Khotyaintsev, Yuri V., Lindqvist, P. -A, Marklund, G. T., Burch, J. L., Torbert, R. B., Ergun, R. E., Goodrich, K. A., Macri, J., Needell, J., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Plaschke, F., Fischer, D., Leinweber, H. K., Anderson, B. J., Le, G., Slavin, J. A., Kepko, E. L., Baumjohann, W., Mauk, B., Fuselier, S. A., and Nakamura, R.

Abstract

Dipolarization fronts (DFs), embedded in bursty bulk flows, play a crucial role in Earth's plasma sheet dynamics because the energy input from the solar wind is partly dissipated in their vicinity. This dissipation is in the form of strong low-frequency waves that can heat and accelerate energetic electrons up to the high-latitude plasma sheet. However, the dynamics of DF propagation and associated low-frequency waves in the magnetotail are still under debate due to instrumental limitations and spacecraft separation distances. In May 2015 the Magnetospheric Multiscale (MMS) mission was in a string-of-pearls configuration with an average intersatellite distance of 160km, which allows us to study in detail the microphysics of DFs. Thus, in this letter we employ MMS data to investigate the properties of dipolarization fronts propagating earthward and associated whistler mode wave emissions. We show that the spatial dynamics of DFs are below the ion gyroradius scale in this region (approximate to 500km), which can modify the dynamics of ions in the vicinity of the DF (e.g., making their motion nonadiabatic). We also show that whistler wave dynamics have a temporal scale of the order of the ion gyroperiod (a few seconds), indicating that the perpendicular temperature anisotropy can vary on such time scales.

Published

2016

45. Observations of whistler mode waves with nonlinear parallel electric fields near the dayside magnetic reconnection separatrix by the Magnetospheric Multiscale mission

Author

Wilder, F. D., Ergun, R. E., Goodrich, K. A., Goldman, M. V., Newman, D. L., Malaspina, D. M., Jaynes, A. N., Schwartz, S. J., Trattner, K. J., Burch, J. L., Argall, M. R., Torbert, R. B., Lindqvist, P. -A, Marklund, G., Le Contel, O., Mirioni, L., Khotyaintsev, Yuri V., Strangeway, R. J., Russell, C. T., Pollock, C. J., Giles, B. L., Plaschke, F., Magnes, W., Eriksson, S., Stawarz, J. E., Sturner, A. P., Holmes, J. C., Wilder, F. D., Ergun, R. E., Goodrich, K. A., Goldman, M. V., Newman, D. L., Malaspina, D. M., Jaynes, A. N., Schwartz, S. J., Trattner, K. J., Burch, J. L., Argall, M. R., Torbert, R. B., Lindqvist, P. -A, Marklund, G., Le Contel, O., Mirioni, L., Khotyaintsev, Yuri V., Strangeway, R. J., Russell, C. T., Pollock, C. J., Giles, B. L., Plaschke, F., Magnes, W., Eriksson, S., Stawarz, J. E., Sturner, A. P., and Holmes, J. C.

Abstract

We show observations from the Magnetospheric Multiscale (MMS) mission of whistler mode waves in the Earth's low-latitude boundary layer (LLBL) during a magnetic reconnection event. The waves propagated obliquely to the magnetic field toward the X line and were confined to the edge of a southward jet in the LLBL. Bipolar parallel electric fields interpreted as electrostatic solitary waves (ESW) are observed intermittently and appear to be in phase with the parallel component of the whistler oscillations. The polarity of the ESWs suggests that if they propagate with the waves, they are electron enhancements as opposed to electron holes. The reduced electron distribution shows a shoulder in the distribution for parallel velocities between 17,000 and 22,000 km/s, which persisted during the interval when ESWs were observed, and is near the phase velocity of the whistlers. This shoulder can drive Langmuir waves, which were observed in the high-frequency parallel electric field data.

Published

2016

46. Whistler mode waves and Hall fields detected by MMS during a dayside magnetopause crossing

Author

Le Contel, O., Retino, A., Breuillard, H., Mirioni, L., Robert, P., Chasapis, A., Lavraud, B., Chust, T., Rezeau, L., Wilder, F. D., Graham, Daniel B., Argall, M. R., Gershman, D. J., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Burch, J. L., Torbert, R. B., Needell, J., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Leinweber, H. K., Plaschke, F., Fischer, D., Anderson, B. J., Le, G., Moore, T. E., Pollock, C. J., Giles, B. L., Dorelli, J. C., Avanov, L., Saito, Y., Le Contel, O., Retino, A., Breuillard, H., Mirioni, L., Robert, P., Chasapis, A., Lavraud, B., Chust, T., Rezeau, L., Wilder, F. D., Graham, Daniel B., Argall, M. R., Gershman, D. J., Lindqvist, P. -A, Khotyaintsev, Yuri V., Marklund, G., Ergun, R. E., Goodrich, K. A., Burch, J. L., Torbert, R. B., Needell, J., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Leinweber, H. K., Plaschke, F., Fischer, D., Anderson, B. J., Le, G., Moore, T. E., Pollock, C. J., Giles, B. L., Dorelli, J. C., Avanov, L., and Saito, Y.

Abstract

We present Magnetospheric Multiscale (MMS) mission measurements during a full magnetopause crossing associated with an enhanced southward ion flow. A quasi-steady magnetospheric whistler mode wave emission propagating toward the reconnection region with quasi-parallel and oblique wave angles is detected just before the opening of the magnetic field lines and the detection of escaping energetic electrons. Its source is likely the perpendicular temperature anisotropy of magnetospheric energetic electrons. In this region, perpendicular and parallel currents as well as the Hall electric field are calculated and found to be consistent with the decoupling of ions from the magnetic field and the crossing of a magnetospheric separatrix region. On the magnetosheath side, Hall electric fields are found smaller as the density is larger but still consistent with the decoupling of ions. Intense quasi-parallel whistler wave emissions are detected propagating both toward and away from the reconnection region in association with a perpendicular anisotropy of the high-energy part of the magnetosheath electron population and a strong perpendicular current, which suggests that in addition to the electron diffusion region, magnetosheath separatrices could be a source region for whistler waves.

Published

2016