Survey of 0.1‐ to 16‐keV/<i>e</i> plasma sheet ion composition

Lennartsson, W.; Shelley, E. G.

doi:10.1029/ja091ia03p03061

Cited by 267 publications

(239 citation statements)

References 26 publications

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“…This phenomenon may well be a fundamental physical aspect of the proton "blasts," but it appears somewhat separate from the energy and pitch angle dispersions in the data, suggesting that the instrument often encounters sharp spatial flux gradients in addition to the temporal effects. For a brief analysis of this aspect, consider again the last couple of dispersion traces in Plate 3, in particular, the one dissected in Extending that line of reasoning to globally active conditions, one may speculate that the central plasma sheet then shows the cumulative effect of widespread "blasting," especially near local midnight, since its temperature peaks there [Lennartsson and Shelley, 1986]. Indeed, the top panel of Plate 3, representing strongly disturbed conditions, has many dispersions spanning some 7 ø invariant latitude, and the slope of the dispersions varies somewhat randomly, as though a large radial range of the near-midnight (---0010 MLT) tail is active concurrently.…”

Section: Spatial Flux Gradientsmentioning

confidence: 99%

“…The number density in the center of the H + trace, at 0933:06 UT, is 0.42 cm -3, whereas the peak O + density, at 0937:13 UT, excluding the upflowing component at lower energy, is 0.07 cm -3, suggesting an O+/H + ratio of •17% at the source. That is fairly typical of the central plasma sheet during geomagnetically active conditions, considering that solar activity at this time is still in its early rising phase [Lennartsson and Shelley, 1986]. …”

Section: Two Equatorward Crossings Of the Plasma Sheet Boundarymentioning

confidence: 99%

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Polar/Toroidal Imaging Mass‐Angle Spectrograph survey of earthward field‐aligned proton flows from the near‐midnight tail

Lennartsson¹,

Trattner²,

Collin³

et al. 2001

J. Geophys. Res.

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Section: Spatial Flux Gradientsmentioning

confidence: 99%

Section: Two Equatorward Crossings Of the Plasma Sheet Boundarymentioning

confidence: 99%

Polar/Toroidal Imaging Mass‐Angle Spectrograph survey of earthward field‐aligned proton flows from the near‐midnight tail

Lennartsson¹,

Trattner²,

Collin³

et al. 2001

J. Geophys. Res.

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“…Magnetotail ion composition measurements in that energy range were first made more than 20 years ago on the ISEE 1 satellite, within 23 R E [Lennartsson and Shelley, 1986, and references therein], and are presently being made with the Cluster satellites within 19 R E [e.g., Rème et al, 2001]. Near-Earth ion composition measurements ($2 R E ) were begun even earlier with the polar-orbiting S3-3 satellite and were indeed the first to both detect the energetic ion outflow and provide substantial statistical material [e.g., Ghielmetti et al, 1978;Collin et al, 1981].…”

Section: Introductionmentioning

confidence: 99%

“…[4] According to the several years of ISEE 1 measurements the virtually omnipresent O + ions, arguably the ''quintessential'' ionosphere origin ions, have a broad energy distribution in the tail plasma sheet beyond 10 R E , typically averaging $3-4 keV [Lennartsson and Shelley, 1986]. This may be contrasted with the (indirect) DE 1 results just quoted and with the finding in this present study that the mean O + energy at R $ 2 R E , near the Polar perigee, is only $0.1-0.4 keV.…”

Section: Introductionmentioning

confidence: 99%

Solar wind control of Earth's H⁺ and O⁺ outflow rates in the 15‐eV to 33‐keV energy range

2004

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[1] Earth's high-latitude outflow of H + and O + ions has been examined with the Toroidal Imaging Mass-Angle Spectrograph instrument on the Polar satellite in the 15-eV to 33-keV energy range over an almost 3-year period near solar minimum (1996)(1997)(1998). This outflow is compared with solar wind plasma and interplanetary magnetic field (IMF) data from the Wind spacecraft, the latter having been time shifted to the subsolar magnetopause and averaged for 15 min prior to each sampling of Earth's magnetic fieldaligned ion flow densities. When the flow data are arranged according to the polarity of the IMF B z (in GSM coordinates) and limited to times with B z > 3 nT or B z < À3 nT, the total rate of ion outflow is seen to be significantly enhanced with negative B z , typically by factors of 2.5-3 for the O + and 1.5-2 for the H + , more than previously reported from similar but less extensive comparisons. With either IMF B z polarity the rate of ion outflow is well correlated with the solar wind energy flow density, especially well with the density of kinetic energy flow. The rate of ion outflow within the instrument's energy range is a strong function of the Polar satellite altitude, increasing almost threefold from perigee (R $ 2 R E ) toward apogee (R $ 4-9 R E ) for O + ions, i.e., up to 10 26 ions s À1 or more per hemisphere. The apogee enhancement may be still larger for the H + , but it is obscured by mantle flow of cusp origin solar H + . Ion mean energy also increases with altitude, leading to about a twentyfold increase in the O + energy flow rate from Polar perigee to apogee altitude, reaching values of 20 GW or more per hemisphere. While the perigee outflow of H + has little or no seasonal modulation, in terms of ions s À1 the O + outflow rates at both altitudes do increase during local summer and so does the rate of cusp origin H + flow near apogee. The latter rate, in fact, has very similar seasonal modulation as the O + rates, suggesting that it has a significant influence on the O + outflow.

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“…In this case we would not expect a large transport of plasma and energy or, in general, a strong interaction between the solar wind and the magnetosphere. However, during the period in which the IMF points northwards, a strong mixing layer is observed (Lennartsson and Shelley, 1986;Mitchell et al, 1987;Fujimoto et al, 1998) at low latitudes. In order to account for this observed exchange of mass and energy it was proposed (Belmont and Chanteur, 1989;Otto and Fairfield, 2000;Nakamura and Fujimoto, 2005) that the velocity shear between the magnetosphere and the magnetosheath leads to the onset of the Kelvin-Helmholtz (KH) instability.…”

Section: Introductionmentioning

confidence: 99%

Kelvin-Helmholtz vortices and secondary instabilities in super-magnetosonic regimes

et al. 2011

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Abstract. The nonlinear behaviour of the Kelvin-Helmholtz instability is investigated with a two-fluid simulation code in both sub-magnetosonic and super-magnetosonic regimes in a two-dimensional configuration chosen so as to represent typical conditions observed at the Earth's magnetopause flanks. It is shown that in super-magnetosonic regimes the plasma density inside the vortices produced by the development of the Kelvin-Helmholtz instability is approximately uniform, making the plasma inside the vortices effectively stable against the onset of secondary instabilities. However, the relative motion of the vortices relative to the plasma flow can cause the formation of shock structures. It is shown that in the region where the shocks are attached to the vortex boundaries the plasma conditions change rapidly and develop large gradients that allow for the onset of secondary instabilities not observed in sub-magnetosonic regimes.

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Survey of 0.1‐ to 16‐keV/e plasma sheet ion composition

Cited by 267 publications

References 26 publications

Polar/Toroidal Imaging Mass‐Angle Spectrograph survey of earthward field‐aligned proton flows from the near‐midnight tail

Polar/Toroidal Imaging Mass‐Angle Spectrograph survey of earthward field‐aligned proton flows from the near‐midnight tail

Solar wind control of Earth's H⁺ and O⁺ outflow rates in the 15‐eV to 33‐keV energy range

Kelvin-Helmholtz vortices and secondary instabilities in super-magnetosonic regimes

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Survey of 0.1‐ to 16‐keV/e plasma sheet ion composition

Cited by 267 publications

References 26 publications

Polar/Toroidal Imaging Mass‐Angle Spectrograph survey of earthward field‐aligned proton flows from the near‐midnight tail

Polar/Toroidal Imaging Mass‐Angle Spectrograph survey of earthward field‐aligned proton flows from the near‐midnight tail

Solar wind control of Earth's H+ and O+ outflow rates in the 15‐eV to 33‐keV energy range

Kelvin-Helmholtz vortices and secondary instabilities in super-magnetosonic regimes

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Solar wind control of Earth's H⁺ and O⁺ outflow rates in the 15‐eV to 33‐keV energy range