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53. Magnetospheric Multiscale Overview and Science Objectives

Author

Burch, J. L, Moore, T. E, Torbert, R. B, and Giles, B. L

Subjects
Astrophysics
Abstract

Magnetospheric Multiscale (MMS), a NASA four-spacecraft constellation mission launched on March 12, 2015, will investigate magnetic reconnection in the boundary regions of the Earth's magnetosphere, particularly along its dayside boundary with the solar wind and the neutral sheet in the magnetic tail. The most important goal of MMS is to conduct a definitive experiment to determine what causes magnetic field lines to reconnect in a collisionless plasma. The significance of the MMS results will extend far beyond the Earth's magnetosphere because reconnection is known to occur in interplanetary space and in the solar corona where it is responsible for solar flares and the disconnection events known as coronal mass ejections. Active research is also being conducted on reconnection in the laboratory and specifically in magnetic-confinement fusion devices in which it is a limiting factor in achieving and maintaining electron temperatures high enough to initiate fusion. Finally, reconnection is proposed as the cause of numerous phenomena throughout the universe such as comet-tail disconnection events, magnetar flares, supernova ejections, and dynamics of neutron-star accretion disks. The MMS mission design is focused on answering specific questions about reconnection at the Earth's magnetosphere. The prime focus of the mission is on determining the kinetic processes occurring in the electron diffusion region that are responsible for reconnection and that determine how it is initiated; but the mission will also place that physics into the context of the broad spectrum of physical processes associated with reconnection. Connections to other disciplines such as solar physics, astrophysics, and laboratory plasma physics are expected to be made through theory and modeling as informed by the MMS results.

Published
2015
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54. Study of Static Microchannel Plate Saturation Effects for the Fast Plasma Investigation Dual Electron Spectrometers on NASA's Magnetospheric MultiScale Mission

Author

Avanov, L. A, Gliese, U, Pollock, C. J, Moore, T. E, Chornay, D. J, Barrie, A. C, Kujawski, J. T, Gershman, D. J, Tucker, C. J, Mariano, A, Smith, D. L, and Jacques, A. D

Subjects
Instrumentation And Photography, Space Sciences (General)
Abstract

Imaging detecting systems based on microchannel plates (MCPs) are the most common for low energy plasma measurements for both space borne and ground applications. One of the key parameters of these detection systems is the dynamic range of the MCP's response to the input fluxes of charged particles. For most applications the dynamic range of the linear response should be as wide as possible. This is especially true for the Dual Electron Spectrometers (DESs) of the Fast Plasma Investigation (FPI) on NASA's Magnetospheric MultiScale (MMS) mission because a wide range of input fluxes are expected. To make use of the full available dynamic range, it is important to understand the MCP response behavior beyond the linear regime where the MCPs start to saturate. We have performed extensive studies of this during the characterization and calibration of the DES instruments and have identified several saturation effects of the detection system. The MCP itself exhibits saturation when the channels lack the ability to replenish charge sufficiently rapidly. It is found and will be shown that the ground system can significantly impact the correct measurement of this effect. As the MCP starts to saturate, the resulting pulse height distribution (PHD) changes shape and location (with less pulse height values), which leads to truncation of the PHD by the threshold set on the detection system discriminator. Finally, the detection system pulse amplifier exhibits saturation as the input flux drives pulse rates greater than its linear response speed. All of these effects effectively change the dead time of the overall detection system and as a result can affect the quality and interpretation of the flight data. We present results of detection system saturation effects and their interaction with special emphasis on the MCP related effects.

Published
2015

55. Impacts of Ionospheric Ions on Magnetic Reconnection and Earth's Magnetosphere Dynamics

Author

Toledo‐Redondo, S., primary, André, M., additional, Aunai, N., additional, Chappell, C. R., additional, Dargent, J., additional, Fuselier, S. A., additional, Glocer, A., additional, Graham, D. B., additional, Haaland, S., additional, Hesse, M., additional, Kistler, L. M., additional, Lavraud, B., additional, Li, W., additional, Moore, T. E., additional, Tenfjord, P., additional, and Vines, S. K., additional

Published
2021
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56. Quantification of Cold-Ion Beams in a Magnetic Reconnection Jet

Author

Li, Yu-Xuan, Li, Wen-Ya, Tang, Bin-Bin, Norgren, C., He, Jian-Sen, Wang, Chi, Zong, Qiu-Gang, Toledo-Redondo, S., André, Mats, Chappell, C., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Kistler, L., Lavraud, B., Moore, T. E., Tenfjord, P., Vines, S. K., Burch, J., Li, Yu-Xuan, Li, Wen-Ya, Tang, Bin-Bin, Norgren, C., He, Jian-Sen, Wang, Chi, Zong, Qiu-Gang, Toledo-Redondo, S., André, Mats, Chappell, C., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Kistler, L., Lavraud, B., Moore, T. E., Tenfjord, P., Vines, S. K., and Burch, J.

Abstract

Cold (few eV) ions of ionospheric origin are widely observed in the lobe region of Earth's magnetotail and can enter the ion jet region after magnetic reconnection is triggered in the magnetotail. Here, we investigate a magnetotail crossing with cold ions in one tailward and two earthward ion jets observed by the Magnetospheric Multiscale (MMS) constellation of spacecraft. Cold ions co-existing with hot plasma-sheet ions form types of ion velocity distribution functions (VDFs) in the three jets. In one earthward jet, MMS observe cold-ion beams with large velocities parallel to the magnetic fields, and we perform quantitative analysis on the ion VDFs in this jet. The cold ions, together with the hot ions, are reconnection outflow ions and are a minor population in terms of number density inside this jet. The average bulk speed of the cold-ion beams is approximately 38% larger than that of the hot plasma-sheet ions. The cold-ion beams inside the explored jet are about one order of magnitude colder than the hot plasma-sheet ions. These cold-ion beams could be accelerated by the Hall electric field in the cold ion diffusion region and the shrinking magnetic field lines through the Fermi effect.

Published
2021
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57. Impacts of Ionospheric Ions on Magnetic Reconnection and Earth's Magnetosphere Dynamics

Author

Toledo-Redondo, S., André, Mats, Aunai, N., Chappell, C. R., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Hesse, M., Kistler, L. M., Lavraud, B., Li, W., Moore, T. E., Tenfjord, P., Vines, S. K., Toledo-Redondo, S., André, Mats, Aunai, N., Chappell, C. R., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Hesse, M., Kistler, L. M., Lavraud, B., Li, W., Moore, T. E., Tenfjord, P., and Vines, S. K.

Abstract

Ionospheric ions (mainly H+, He+, and O+) escape from the ionosphere and populate the Earth's magnetosphere. Their thermal energies are usually low when they first escape the ionosphere, typically a few electron volt to tens of electron volt, but they are energized in their journey through the magnetosphere. The ionospheric population is variable, and it makes significant contributions to the magnetospheric mass density in key regions where magnetic reconnection is at work. Solar wind—magnetosphere coupling occurs primarily via magnetic reconnection, a key plasma process that enables transfer of mass and energy into the near-Earth space environment. Reconnection leads to the triggering of magnetospheric storms, auroras, energetic particle precipitation and a host of other magnetospheric phenomena. Several works in the last decades have attempted to statistically quantify the amount of ionospheric plasma supplied to the magnetosphere, including the two key regions where magnetic reconnection occurs: the dayside magnetopause and the magnetotail. Recent in situ observations by the Magnetospheric Multiscale spacecraft and associated modeling have advanced our current understanding of how ionospheric ions alter the magnetic reconnection process, including its onset and efficiency. This article compiles the current understanding of the ionospheric plasma supply to the magnetosphere. It reviews both the quantification of these sources and their effects on the process of magnetic reconnection. It also provides a global description of how the ionospheric ion contribution modifies the way the solar wind couples to the Earth's magnetosphere and how these ions modify the global dynamics of the near-Earth space environment. Plain Language Summary Above the neutral atmosphere, space is filled with charged particles, which are tied to the Earth's magnetic field. The particles come from two sources, the solar wind and the Earth's upper atmosphere. Most of the solar wind particles a

Published
2021
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58. 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
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60. The IBEX-Lo Sensor

Author

Fuselier, S. A., Bochsler, P., Chornay, D., Clark, G., Crew, G. B., Dunn, G., Ellis, S., Friedmann, T., Funsten, H. O., Ghielmetti, A. G., Googins, J., Granoff, M. S., Hamilton, J. W., Hanley, J., Heirtzler, D., Hertzberg, E., Isaac, D., King, B., Knauss, U., Kucharek, H., Kudirka, F., Livi, S., Lobell, J., Longworth, S., Mashburn, K., McComas, D. J., Möbius, E., Moore, A. S., Moore, T. E., Nemanich, R. J., Nolin, J., O’Neal, M., Piazza, D., Peterson, L., Pope, S. E., Rosmarynowski, P., Saul, L. A., Scherrer, J. R., Scheer, J. A., Schlemm, C., Schwadron, N. A., Tillier, C., Turco, S., Tyler, J., Vosbury, M., Wieser, M., Wurz, P., and Zaffke, S.

Published
2009
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61. Kinetic Interaction of Cold and Hot Protons With an Oblique EMIC Wave Near the Dayside Reconnecting Magnetopause

Author

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

Published
2021
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62. A Tailward Moving Current Sheet Normal Magnetic Field Front Followed by an Earthward Moving Dipolarization Front

Author

Hwang, K.-J, Goldstein, M. L, Moore, T. E, Walsh, B. M, Baishev, D. G, Moiseyev, A. V, Shevtsov, B. M, and Yumoto, K

Subjects
Solar Physics
Abstract

A case study is presented using measurements from the Cluster spacecraft and ground-based magnetometers that show a substorm onset propagating from the inner to outer plasma sheet. On 3 October 2005, Cluster, traversing an ion-scale current sheet at the near-Earth plasma sheet, detected a sudden enhancement of Bz, which was immediately followed by a series of flux rope structures. Both the local Bz enhancement and flux ropes propagated tailward. Approximately 5 min later, another Bz enhancement, followed by a large density decrease, was observed to rapidly propagate earthward. Between the two Bz enhancements, a significant removal of magnetic flux occurred, possibly resulting from the tailward moving Bz enhancement and flux ropes. In our scenario, this flux removal caused the magnetotail to be globally stretched so that the thinnest sheet formed tailward of Cluster. The thinned current sheet facilitated magnetic reconnection that quickly evolved from plasma sheet to lobe and generated the later earthward moving dipolarization front (DF) followed by a reduction in density and entropy. Ground magnetograms located near the meridian of Cluster's magnetic foot points show two-step bay enhancements. The positive bay associated with the first Bz enhancement indicates that the substorm onset signatures propagated from the inner to the outer plasma sheet, consistent with the Cluster observation. The more intense bay features associated with the later DF are consistent with the earthward motion of the front. The event suggests that current disruption signatures that originated in the near-Earth current sheet propagated tailward, triggering or facilitating midtail reconnection, thereby preconditioning the magnetosphere for a later strong substorm enhancement.

Published
2014
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63. Direct measurements of two-way wave-particle energy transfer in a collisionless space plasma

Author

Gershman, D. J., Vinas, A. F., Giles, B. L., Moore, T. E., Paterson, W. R., Pollock, C. J., Russell, C. T., Strangeway, R. J., Fuselier, S. A., Burch, J. L., Kitamura, Naritoshi, Kitahara, Masahiro, Shoji, Masafumi, Miyoshi, Yoshizumi, Hasegawa, Hiroshi, Nakamura, Satoko, Katoh, Yuto, Saito, Yoshifumi, Yokota, Shoichiro, Paterson, William R., Russell, Christopher T., and Burch, James L.

Subjects
Physics, Multidisciplinary, 010504 meteorology & atmospheric sciences, Waves in plasmas, Cyclotron, Cyclotron resonance, Magnetosphere, Plasma, 01 natural sciences, Ion, law.invention, Computational physics, Particle acceleration, law, 0103 physical sciences, Astrophysical plasma, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Abstract

著者人数: 19名, Accepted: 2018-07-04, 資料番号: SA1180092000

Published
2018

64. A Statistical Study of Slow-Mode Shocks Observed by MMS in the Dayside Magnetopause

Author

Walia, N. K., Pollock, C. J., Giles, B. L., Moore, T. E., Torbert, R. B., Russell, C. T., Burch, J. L., Seki, Kanako, Hoshino, Masahiro, Amano, Takanobu, Kitamura, Naritoshi, Saito, Yoshifumi, and Yokota, Shoichiro

Subjects
Physics, Geophysics, 010504 meteorology & atmospheric sciences, 0103 physical sciences, Mode (statistics), General Earth and Planetary Sciences, Magnetopause, Magnetic reconnection, 010303 astronomy & astrophysics, 01 natural sciences, 0105 earth and related environmental sciences, Computational physics
Abstract

著者人数: 13名, Accepted: 2018-05-14, 資料番号: SA1180024000

Published
2018

76. 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., Breuillard, H., Argall, M. R., Graham, D. 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, Yu. V., Norgren, C., 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., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Turner, D. L., Fennell, J. F., Leonard, T., Jaynes, A. N., Nakamura, Rumi, and Saito, Yoshifumi

Abstract

著者人数: 48名, Accepted: 2017-10-10, 資料番号: SA1170207000

Published
2017

79. Snowplow Injection Front Effects

Author

Moore, T. E, Chandler, M. O, Buzulukova, N, Collinson, G. A, Kepko, E. L, Garcia-Sage, K. S, Henderson, M. G, and Sitnov, M. I

Subjects
Plasma Physics
Abstract

As the Polar spacecraft apogee precessed through the magnetic equator in 2001, Polar encountered numerous substorm events in the region between geosynchronous orbit and 10 RE geocentric distance; most of them in the plasma sheet boundary layers. Of these, a small number was recorded near the neutral sheet in the evening sector. Polar/Thermal Ion Dynamics Experiment provides a unique perspective on the lowest-energy ion plasma, showing that these events exhibited a damped wavelike character, initiated by a burst of radially outward flow transverse to the local magnetic field at approximately 80 km/s. They then exhibit strongly damped cycles of inward/outward flow with a period of several minutes. After one or two cycles, they culminated in a hot plasma electron and ion injection, quite similar to those observed at geosynchronous orbit. Cold plasmaspheric plasmas comprise the outward flow cycles, while the inward flow cycles contain counterstreaming field-parallel polar wind-like flows. The observed wavelike structure, preceding the arrival of an earthward moving substorm injection front, suggests an outward displacement driven by the inward motion at local times closer to midnight, that is, a "snowplow" effect. The damped in/out flows are consistent with interchange oscillations driven by the arrival at the observed local time by an injection originating at greater radius and local time.

Published
2013
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80. The IBEX-Lo Sensor

Author

Fuselier, S. A., primary, Bochsler, P., additional, Chornay, D., additional, Clark, G., additional, Crew, G. B., additional, Dunn, G., additional, Ellis, S., additional, Friedmann, T., additional, Funsten, H. O., additional, Ghielmetti, A. G., additional, Googins, J., additional, Granoff, M. S., additional, Hamilton, J. W., additional, Hanley, J., additional, Heirtzler, D., additional, Hertzberg, E., additional, Isaac, D., additional, King, B., additional, Knauss, U., additional, Kucharek, H., additional, Kudirka, F., additional, Livi, S., additional, Lobell, J., additional, Longworth, S., additional, Mashburn, K., additional, McComas, D. J., additional, Möbius, E., additional, Moore, A. S., additional, Moore, T. E., additional, Nemanich, R. J., additional, Nolin, J., additional, O’Neal, M., additional, Piazza, D., additional, Peterson, L., additional, Pope, S. E., additional, Rosmarynowski, P., additional, Saul, L. A., additional, Scherrer, J. R., additional, Scheer, J. A., additional, Schlemm, C., additional, Schwadron, N. A., additional, Tillier, C., additional, Turco, S., additional, Tyler, J., additional, Vosbury, M., additional, Wieser, M., additional, Wurz, P., additional, and Zaffke, S., additional

Published
2009
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81. On the Ubiquity of Magnetic Reconnection Inside Flux Transfer Event‐Like Structures at the Earth's Magnetopause

Author

Fargette, N., primary, Lavraud, B., additional, Øieroset, M., additional, Phan, T. D., additional, Toledo‐Redondo, S., additional, Kieokaew, R., additional, Jacquey, C., additional, Fuselier, S. A., additional, Trattner, K. J., additional, Petrinec, S., additional, Hasegawa, H., additional, Garnier, P., additional, Génot, V., additional, Lenouvel, Q., additional, Fadanelli, S., additional, Penou, E., additional, Sauvaud, J.‐A., additional, Avanov, D. L. A., additional, Burch, J., additional, Chandler, M. O., additional, Coffey, V. N., additional, Dorelli, J., additional, Eastwood, J. P., additional, Farrugia, C. J., additional, Gershman, D. J., additional, Giles, B. L., additional, Grigorenko, E., additional, Moore, T. E., additional, Paterson, W. R., additional, Pollock, C., additional, Saito, Y., additional, Schiff, C., additional, and Smith, S. E., additional

Published
2020
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82. Multiscale Studies of the Three-Dimensional Dayside X-Line

Author

Moore, T. E, Burch, J. L, Daughton, W. S, Fuselier, S. A, Hasegawa, H, Petrinec, S. M, and Pu, Zuyin

Subjects
Plasma Physics
Abstract

We review recent experience from the Cluster, Double Star, and THEMIS missions for lessons that apply to the upcoming Magnetospheric Multiscale Mission (MMS) being developed for launch in 2014. On global scales, simulation and statistical studies lead to mean congurations of dayside reconnection, implying specific relative alignments of the inflow magnetic fields and X-line, with implications for MMS operations designed to maximize the number of close encounters with the diffusion region. At intermediate MHD-to-ion scales, reconstruction of features created by one or two X-lines have developed to the point where data from a cluster of spacecraft can determine their temporal trends and the approximate three-dimensional X-line structure. Recent petascale particle-in-cell (PIC) simulations of reconnection encompass three spatial dimensions with excellent resolution, and make striking predictions of electron scale physics that creates complex interacting flux ropes under component reconnection. High time resolution measurements from MMS will determine the detailed electron scale kinetics embedded within the global and MHDion scale contexts. These developments will lead to the refinement of our three-dimensional multiscale picture of reconnection, yielding improved understanding of the global, MHD, and local physics controlling the onset or quenching, variability, and mean rate of reconnection. This in turn will enable improved predictability of the structural features created by transient reconnection, and their space weather consequences.

Published
2012
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83. Short Large-Amplitude Magnetic Structures (SLAMS) at Venus

Author

Collinson, G. A, Wilson, L. B, Sibeck, D. G, Shane, N, Zhang, T. L, Moore, T. E, Coates, A. J, and Barabash, S

Subjects
Astrophysics
Abstract

We present the first observation of magnetic fluctuations consistent with Short Large-Amplitude Magnetic Structures (SLAMS) in the foreshock of the planet Venus. Three monolithic magnetic field spikes were observed by the Venus Express on the 11th of April 2009. The structures were approx.1.5->11s in duration, had magnetic compression ratios between approx.3->6, and exhibited elliptical polarization. These characteristics are consistent with the SLAMS observed at Earth, Jupiter, and Comet Giacobini-Zinner, and thus we hypothesize that it is possible SLAMS may be found at any celestial body with a foreshock.

Published
2012

84. Heliospheric Neutral Atom Spectra Between 0.01 and 6 keV fom IBEX

Author

Fuselier, S. A, Allegrini, F, Bzowski, M, Funsten, H. O, Ghielmetti, A. G, Gloeckler, G, Heirtzler, D, Janzen, P, Kubiak, M, Kucharek, H, McComas, D. J, Moebius, E, Moore, T. E, Petrinec, S. M, Quinn, M, Reisenfeld, D, Saul, L. A, Scheer, J. A, Schwardron, N, Trattner, K. J, Vanderspek, R, and Wurz, P

Subjects
Lunar And Planetary Science And Exploration
Abstract

Since 2008 December, the Interstellar Boundary Explorer (IBEX) has been making detailed observations of neutrals from the boundaries of the heliosphere using two neutral atom cameras with overlapping energy ranges. The unexpected, yet defining feature discovered by IBEX is a Ribbon that extends over the energy range from about 0.2 to 6 keV. This Ribbon is superposed on a more uniform, globally distributed heliospheric neutral population. With some important exceptions, the focus of early IBEX studies has been on neutral atoms with energies greater than approx. 0.5 keV. With nearly three years of science observations, enough low-energy neutral atom measurements have been accumulated to extend IBEX observations to energies less than approx. 0.5 keV. Using the energy overlap of the sensors to identify and remove backgrounds, energy spectra over the entire IBEX energy range are produced. However, contributions by interstellar neutrals to the energy spectrum below 0.2 keV may not be completely removed. Compared with spectra at higher energies, neutral atom spectra at lower energies do not vary much from location to location in the sky, including in the direction of the IBEX Ribbon. Neutral fluxes are used to show that low energy ions contribute approximately the same thermal pressure as higher energy ions in the heliosheath. However, contributions to the dynamic pressure are very high unless there is, for example, turbulence in the heliosheath with fluctuations of the order of 50-100 km/s.

Published
2012
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85. Plasma Outflows: Known Knowns, Known Unknowns, and The Unknown

Author

Moore, T. E

Subjects
Plasma Physics
Abstract

A brief summary is given of i) what we know from observing ionospheric outflows and ii) how outflow parameterizations are being used in global simulations to evaluate their effects on magnetospheric dynamics. Then, a list of unanswered questions and issues to be resolved is given, followed by a description of the known future mission plans expressed in the Heliophysics Roadmap, such as Origin of Near-Earth Plasmas (ONEP), and Ion-Neutral Coupling in the Atmosphere (INCA). Finally, a set of requirements for definitive plasma outflow observations are identified, along with possible methods for fulfilling them in future missions. Since results of the current Heliophysics Decadal Survey are expected soon, it is hoped that future plans can be summarized and discussed without speculation at the GEM 2012 meeting.

Published
2012

86. High‐density O+ in Earth's outer magnetosphere and its effect on dayside magnetopause magnetic reconnection

Author

Fuselier, S. A., primary, Mukherjee, J., additional, Denton, M. H., additional, Petrinec, S. M., additional, Trattner, K. J., additional, Toledo‐Redondo, S., additional, André, M., additional, Aunai, N., additional, Chappell, C. R., additional, Glocer, A., additional, Haaland, S., additional, Hesse, M., additional, Kistler, L. M., additional, Lavraud, B., additional, Li, W. Y., additional, Moore, T. E., additional, Graham, D., additional, Tenfjord, P., additional, Dargent, J., additional, Vines, S. K., additional, Strangeway, R. J., additional, and Burch, J. L., additional

Published
2019
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87. Electrostatic Spacecraft Potential Structure and Wake Formation Effects for Characterization of Cold Ion Beams in the Earth's Magnetosphere

Author

Toledo‐Redondo, S., primary, Lavraud, B., additional, Fuselier, S. A., additional, André, M., additional, Khotyaintsev, Yu. V., additional, Nakamura, R., additional, Escoubet, C. P., additional, Li, W. Y., additional, Torkar, K., additional, Cipriani, F., additional, Barrie, A. C., additional, Giles, B., additional, Moore, T. E., additional, Gershman, D., additional, Lindqvist, P.‐A., additional, Ergun, R. E., additional, Russell, C. T., additional, and Burch, J. L., additional

Published
2019
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88. Two Azimuthally Separated Regions of Cusp Ion Injection Observed via Energetic Neutral Atoms

Author

Abe, M, Taguchi, S, Collier, M. R, and Moore, T. E

Subjects
Geophysics
Abstract

The low-energy neutral atom (LENA) imager on the IMAGE spacecraft can detect energetic neutral atoms produced by ion injection into the cusp through a charge exchange with the Earth's hydrogen exosphere. We examined the occurrence of the LENA cusp signal during positive IMF B(sub z) in terms of the arrival direction and the IMF clock angle theta(sub CA). Results of statistical analyses show that the occurrence frequency is high on the postnoon side when theta(sub CA) is between approximately 20 degrees and approximately 50 degrees. This is ascribed to ion injection caused by cusp reconnection typical of positive IMF B(sub z). Our results also show that there is another situation of high occurrence frequency, which can be identified with theta(sub CA) of approximately 30 degrees to approximately 80 degrees. When theta(sub CA) is relatively large (60 degrees - 80 degrees), occurrence frequencies are high at relatively low latitudes over a wide extent spanning both prenoon and postnoon sectors. This feature suggests that the ion injection is caused by reconnection at the dayside magnetopause. Its postnoon side boundary shifts toward the prenoon as theta(sub CA) decreases. When theta(sub CA) is less than approximately 50 degrees, the high occurrence frequency exists well inside the prenoon sector, which is azimuthally separated from the postnoon region ascribed to cusp reconnection. The prenoon region, which is thought due to ion injection caused by dayside reconnection, may explain the recent report that proton aurora brightening occurs in the unanticipated prenoon sector of the northern high-latitude ionosphere for IMF B(sub y) greater than 0 and B(sub z) greater than 0.

Published
2011
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89. On the Effect of IMF Turning on Ion Dynamics at Mercury

Author

Delcourt, D. C, Moore, T. E, and Fok, M.-C. H

Subjects
Geophysics
Abstract

We investigate the effect of a rotation of the Interplanetary Magnetic Field (IMF) on the transport of magnetospheric ion populations at Mercury. We focus on ions of planetary origin and investigate their large-scale circulation using three-dimensional single-particle simulations. We show that a nonzero Bx component of the IMF leads to a pronounced asymmetry in the overall circulation pattern . In particular, we demonstrate that the centrifugal acceleration due to curvature of the E x B drift paths is more pronounced in one hemisphere than the other, leading to filling of the magnetospheric lobes and plasma sheet with more or less energetic material depending upon the hemisphere of origin. Using a time-varying electric and magnetic field model, we investigate the response of ions to rapid (a few tens of seconds) re-orientation of the IMF. We show that, for ions with gyroperiods comparable to the field variation time scale, the inductive electric field should lead to significant nonadiabatic energization, up to several hundreds of eVs or a few keVs. It thus appears that IMP turning at Mercury should lead to localized loading of the magnetosphere with energetic material of planetary origin (e.g., Na+).

Published
2011
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90. Generalized Jeans' Escape of Pick-Up Ions in Quasi-Linear Relaxation

Author

Moore, T. E and Khazanov, G. V

Subjects
Astrophysics
Abstract

Jeans escape is a well-validated formulation of upper atmospheric escape that we have generalized to estimate plasma escape from ionospheres. It involves the computation of the parts of particle velocity space that are unbound by the gravitational potential at the exobase, followed by a calculation of the flux carried by such unbound particles as they escape from the potential well. To generalize this approach for ions, we superposed an electrostatic ambipolar potential and a centrifugal potential, for motions across and along a divergent magnetic field. We then considered how the presence of superthermal electrons, produced by precipitating auroral primary electrons, controls the ambipolar potential. We also showed that the centrifugal potential plays a small role in controlling the mass escape flux from the terrestrial ionosphere. We then applied the transverse ion velocity distribution produced when ions, picked up by supersonic (i.e., auroral) ionospheric convection, relax via quasi-linear diffusion, as estimated for cometary comas [1]. The results provide a theoretical basis for observed ion escape response to electromagnetic and kinetic energy sources. They also suggest that super-sonic but sub-Alfvenic flow, with ion pick-up, is a unique and important regime of ion-neutral coupling, in which plasma wave-particle interactions are driven by ion-neutral collisions at densities for which the collision frequency falls near or below the gyro-frequency. As another possible illustration of this process, the heliopause ribbon discovered by the IBEX mission involves interactions between the solar wind ions and the interstellar neutral gas, in a regime that may be analogous [2].

Published
2011

93. Mechanisms of Ionospheric Mass Escape

Author

Moore, T. E and Khazanov, G. V

Subjects
Geophysics
Abstract

The dependence of ionospheric O+ escape flux on electromagnetic energy flux and electron precipitation into the ionosphere is derived for a hypothetical ambipolar pick-up process, powered the relative motion of plasmas and neutral upper atmosphere, and by electron precipitation, at heights where the ions are magnetized but influenced by photo-ionization, collisions with gas atoms, ambipolar and centrifugal acceleration. Ion pick-up by the convection electric field produces "ring-beam" or toroidal velocity distributions, as inferred from direct plasma measurements, from observations of the associated waves, and from the spectra of incoherent radar echoes. Ring-beams are unstable to plasma wave growth, resulting in rapid relaxation via transverse velocity diffusion, into transversely accelerated ion populations. Ion escape is substantially facilitated by the ambipolar potential, but is only weakly affected by centrifugal acceleration. If, as cited simulations suggest, ion ring beams relax into non-thermal velocity distributions with characteristic speed equal to the local ion-neutral flow speed, a generalized "Jeans escape" calculation shows that the escape flux of ionospheric O+ increases with Poynting flux and with precipitating electron density in rough agreement with observations.

Published
2010

94. Dynamics of Ring Current and Electric Fields in the Inner Magnetosphere During Disturbed Periods: CRCM-BATS-R-US Coupled Model

Author

Buzulukova, N, Fok, M.-C, Pulkkinen, A, Kuznetsova, M, Moore, T. E, Glocer, A, Brandt, P. C, Toth, G, and Rastaetter, L

Subjects
Geophysics
Abstract

We present simulation results from a one-way coupled global MHD model (Block-Adaptive-Tree Solar-Wind Roe-Type Upwind Scheme, BATS-R-US) and kinetic ring current models (Comprehensive Ring Current Model, CRCM, and Fok Ring Current, FokRC). The BATS-R-US provides the CRCM/FokRC with magnetic field information and plasma density/temperature at the polar CRCM/FokRC boundary. The CRCM uses an electric potential from the BATS-R-US ionospheric solver at the polar CRCM boundary in order to calculate the electric field pattern consistent with the CRCM pressure distribution. The FokRC electric field potential is taken from BATS-R-US ionospheric solver everywhere in the modeled region, and the effect of Region II currents is neglected. We show that for an idealized case with southward-northward-southward Bz IMF turning, CRCM-BATS-R-US reproduces well known features of inner magnetosphere electrodynamics: strong/weak convection under the southward/northward Bz; electric field shielding/overshielding/penetration effects; an injection during the substorm development; Subauroral Ion Drift or Polarization Jet (SAID/PJ) signature in the dusk sector. Furthermore, we find for the idealized case that SAID/PJ forms during the substorm growth phase, and that substorm injection has its own structure of field-aligned currents which resembles a substorm current wedge. For an actual event (12 August 2000 storm), we calculate ENA emissions and compare with Imager for Magnetopause-to-Aurora Global Exploration/High Energy Neutral Atom data. The CRCM-BATS-R-US reproduces both the global morphology of ring current and the fine structure of ring current injection. The FokRC-BATS-R-US shows the effect of a realistic description of Region II currents in ring current-MHD coupled models.

Published
2010
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95. Global Response to Local Ionospheric Mass Ejection

Author

Moore, T. E, Fok, M.-C, Delcourt, D. C, Slinker, S. P, and Fedder, J. A

Subjects
Geophysics
Abstract

We revisit a reported "Ionospheric Mass Ejection" using prior event observations to guide a global simulation of local ionospheric outflows, global magnetospheric circulation, and plasma sheet pressurization, and comparing our results with the observed global response. Our simulation framework is based on test particle motions in the Lyon-Fedder-Mobarry (LFM) global circulation model electromagnetic fields. The inner magnetosphere is simulated with the Comprehensive Ring Current Model (CRCM) of Fok and Wolf, driven by the transpolar potential developed by the LFM magnetosphere, and includes an embedded plasmaspheric simulation. Global circulation is stimulated using the observed solar wind conditions for the period 24-25 Sept 1998. This period begins with the arrival of a Coronal Mass Ejection, initially with northward, but later with southward interplanetary magnetic field. Test particles are launched from the ionosphere with fluxes specified by local empirical relationships of outflow to electrodynamic and particle precipitation imposed by the MIlD simulation. Particles are tracked until they are lost from the system downstream or into the atmosphere, using the full equations of motion. Results are compared with the observed ring current and a simulation of polar and auroral wind outflows driven globally by solar wind dynamic pressure. We find good quantitative agreement with the observed ring current, and reasonable qualitative agreement with earlier simulation results, suggesting that the solar wind driven global simulation generates realistic energy dissipation in the ionosphere and that the Strangeway relations provide a realistic local outflow description.

Published
2010

98. Kinetic Effects of Cold Plasma on Magnetospheric EMIC Waves

Author

Toledo-Redondo, Sergio, Lavraud, B., Fuselier, S. A., Le Contel, Olivier, Moore, T. E., Giles, B. L., Lindqvist, P. A., Russell, C. T., Institut de recherche en astrophysique et planétologie (IRAP), Institut national des sciences de l'Univers (INSU - CNRS)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Observatoire Midi-Pyrénées (OMP), Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Physique des Plasmas (LPP), Université Paris-Saclay-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-École polytechnique (X)-Observatoire de Paris, and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)

Subjects
Physics::Plasma Physics, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], Physics::Space Physics, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]
Abstract

International audience; The Earth's magnetosphere is populated by particles coming from the Earth's ionosphere and the solar wind. The ionospheric component is often composed by cold (below tens of eV) ions, and it has been shown that these cold ions introduce a shorter length-scale into plasma processes like magnetic reconnection, owing to their smaller gyroradius than hot magnetospheric ions. In addition, Electromagnetic Ion Cyclotron (EMIC) waves do occur in the outer magnetosphere, often in association with ionospheric ions, and serve as a coupling mechanism to the ionosphere and inner magnetosphere. Using the MMS fleet, we investigate the dynamics of these waves when cold ions are present, and compare them to cases without the cold ion component. The short separation between spacecraft plus the high time resolution of MMS allows us to resolve the kinetic properties of these waves with unprecedented detail. When cold ions are present, the wave becomes kinetic to the (hot) ring current ions, whereas the cold ions remain largely magnetized. This results into cold ion trapping that produces density enhancements, which in turn may be linked to the generation of whistlers.

Published
2018

99. Turbulence Studies using MMS: data issues and physics

Author

Bandyopadhyay, R., Matthaeus, W. H., Chasapis, A., Chhiber, R., Parashar, T., Maruca, B. A., Shay, M. A., Schwartz, S. J., Eriksson, S., Le Contel, Olivier, Breuillard, Hugo, Burch, J. L., Moore, T. E., Pollock, C., Giles, B. L., Dorelli, J. C., Gershman, D. J., Torbert, R. B., Russell, C. T., Strangeway, R. J., Laboratoire de Physique des Plasmas (LPP), Université Paris-Saclay-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-École polytechnique (X)-Observatoire de Paris, and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)

Subjects
[PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], Physics::Space Physics, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]
Abstract

International audience; Magnetospheric Multiscale (MMS) Mission offers measurements of magnetic field, proton and electron moments spanning a broad range of length-scales, from energy containing scales to kinetic scales. The very high time-resolution of the plasma instruments onboard MMS along with the availability of simultaneous measurements from four spacecraft, separated by sub-proton scale distances, make MMS observations an excellent case for study of multi-scale turbulence in near-Earth space plasmas. We calculate the energy transfer rate in the Earth's magnetosheath using two different methods at separate scales. A Karman-Howarth decay phenomenology gives the global energy budget at the energy containing scales. An estimation of inertial range cascade rate is made using Politano-Pouqet third-order law for MHD. We find that the estimates of the energy transfer rates at the large scales and in the inertial scales agree well with each other, providing a confirmation of the assumption of constant energy cascade across those scales. We further measure the incompressive channel of the cascade rate at kinetic scales by evaluating the classical incompressible third-order law at the kinetic scales, using a mutil-spacecraft technique. To use MMS data in the pristine solar wind some processing is required. We provide a procedure to use the measurements of FPI moments in the pristine solar wind. After processing the data, we measure the incompressive energy transfer rate in the solar wind using the third-order law, similar to the magnetosheath case. We find that the energy transfer rate in the magnetosheath is about 1000 times larger than the transfer rate in the solar wind. The higher rate of energy decay rate in the magnetosheath is consistent with the fact the plasma in the sheath is hotter than the solar wind plasma.

Published
2018

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