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11.
The high electron temperatures existing within SAR-arcs can result in enhanced vibrational excitation of atmospheric N2 molecules and, as a consequence, increase the rate coefficient of the reaction, O+ + N2 → NO+ + N. This results in a change in the relative abundance of O+ and NO++ in the SAR-arc region compared with that in the undisturbed ionosphere. Theoretical ion density profiles were computed by a triple ion analysis solving the mass, momentum and energy equations for O+, NO+ and O+2 ions self-consistently. Although the electron temperature dependence of the recombination rate of NO+ is not well known, the results show that for a range of expected recombination rates NO+ still remains the dominant ion up to ca. 320 km at night within a bright SAR-arc. Studies were also made of the relative importance of a downward O+ flux and an upward ion drift in maintaining the F-region under SAR-arc conditions. It was found that the upward drift caused a marked increase in the NO+/O+ transition altitude as high as 460 km at night. However, for typical drift speeds up to 50 m sec?1 the peak electron density was lower than experimental observations. The effect of a large, short-duration perpendicular electric field on the SAR-arc ion and electron density profiles was found to be small. In all cases considered the magnitude of the enhanced NO+ density as a result of vibrationally excited N2 molecules was sufficient to prevent the electron density within the night-time SAR-arc from becoming vanishingly small. 相似文献
12.
Measurements of thermospheric electron temperatures at altitudes in the range 250–1100 km, made with a Langmuir probe carried on the polar-orbiting satellite ESRO-4, have been used to derive model functions of electron temperature in terms of altitude, magnetic latitude and local time for the periods November 1972 to June 1973 and March to October 1973. The technique used to compute the coefficients of the model functions is described, and the model electron temperatures are compared with those obtained from similar instruments on the Ariel-1 satellite in 1962 and the ESRO-1A satellite in 1968–1969, and from ground-based observatories. The models reproduce the major features of topside electron distributions viz. mid-day temperatures exceeding midnight temperatures by about 500 K, dawn enhancement leading to peak temperatures greater than mid-day values particularly around 50° magnetic latitude, and temperatures increasing with altitude at all latitudes and with latitude at all altitudes. The daytime mid-latitude temperature is used to complete a series of observations by various techniques over a solar cycle and thereby to confirm the sense and degree of solar cycle control on the thermospheric electron temperature predicted by theoretical considerations. 相似文献
13.
Observations are reported of field aligned etectron fluxes in the energy range 50–500 eV at altitudes below 270 km from two rocket flights in the auroral zone. The regions of field aligned suprathermal electrons occurred in bursts of a few seconds duration, and in some instances the energy of the peak field aligned flux was in the range 100–500 eV. Theoretical calculations of the pitch angle distribution were made using the Monte Carlo technique for two model atmospheres having exospheric temperatures of 750 and 1500 K bracketing the expected auroral zone exospheric temperature. The calculations were made for the case of incident field aligned suprathermal fluxes with no local parallel electric field and also for the case of a local constant parallel electric field. Comparison of theoretical and experimental pitch angle distributions showed that in one case at 270 km a parallel electric field of 1–2 mV/m fitted the data whereas another burst at 210 km required a parallel electric field of about 10 mV/m to produce a field aligned distribution of 230 eV electrons as pronounced as was observed. Furthermore in this latter case the lack of strong field alignment at 500 eV pointed to localisation of the parallel electric field to an altitude range of 20–30 km about the rocket altitude. 相似文献
14.
We consider macroscopic flow of energy and momentum between the solar wind and outer magnetosphere. We point out that using the integral form of magnetohydrodynamic equations is more natural than the differential form for consideration of energy and momentum flows and should yield more accurate results from magnetic field data. We use the notation of general relativity because it is straightforward and brief. 相似文献
15.
The continuity, momentum and energy hydrodynamic equations for an H+-O+ topside ionosphere have been solved self-consistently for steady state conditions similar to those found outside the plasmasphere. Results are given for undisturbed and trough conditions with a range of H+ outflow velocities yielding subsonic and supersonic flow. In the formulation of the equations, account was taken of the velocity dependence of ion-neutral, ion-ion and ion-electron collision frequencies. In addition, parallel stress and the nonlinear acceleration term were retained in the H+ momentum equation. Results computed from this model show that, as a result of Joule (frictional) heating, the H+ temperature rises with increasing outflow velocity in the subsonic flow regime, reaching a maximum value of about 4000 K. For supersonic flow other terms in the H+ momentum equation become important and alter the H+ velocity profile such that convection becomes a heat sink in the 1000–1500 km altitude range. This, together with the reduced Joule heating resulting from the high-speed velocity dependence of the H+ collision frequencies, results in a decrease in the H+ temperature as the outflow velocity increases. However, for all outward flows the H+ temperature remains substantially greater than the O+ temperature. With identical upper boundary velocities, the H+ flow velocity is higher at low altitudes for trough conditions compared with non-trough conditions, but the H+ temperature in the trough is lower. The form of the H+ density profiles for supersonic flow does not in general differ greatly from those obtained with wholly subsonic flow conditions. 相似文献
16.
The total ion current probe on the satellite ESRO-4 monitored thermal plasma density variations in the range ± 30% of ambient density with a spatial resolution of about 1.5 km. Latitudinal, diurnal, and altitudinal characteristics of density irregularities in the topside ionosphere have been investigated using the 2 × 108 total ion current values recorded during the lifetime of the satellite. Dominating the morphology of topside irregularities is the high-latitude zone evident throughout the day, with the appearance of a distinct sub-auroral zone at night. Significant mid-latitude irregularity occurs at low altitudes during the night. The results reported here provide the most comprehensive study of topside ionospheric irregularities from direct probe measurements, and reveal new evidence on possible irregularity production mechanisms. 相似文献
17.
The paper presents some initial results on measurements of the thermal plasma environment obtained by a spherical retarding potential analyzer and a Langmuir probe flown on the third space shuttle flight (STS-3) as part of the NASA Office of Space Science-1 (OSS-1) payload in March 1982. One of the major effects observed is a higher degree of turbulence in the ambient plasma compared to what is observed from similar instruments flown on unmanned satellites. In addition we see the temperature of the thermal electrons elevated to values of 4000–5000 K. Associated with elevated electron temperatures are regions of enhanced plasma density resulting from the appearance of high densities of molecular ions. The thermal plasma data also show clear effects of an induced V × B · L potential at the location of the probes which matches that produced by an L vector linking the probes to the engine nozzles; thereby establishing the prime return current location on the Orbiter. The final observations discussed are the pronounced and complex wake effects resulting both from the main structure of the Orbiter and from the complex shapes of appendages attached to the Orbiter. 相似文献
18.
Position of the mid-latitude trough in the topside ionosphere as deduced from ESRO 4 observations 总被引:1,自引:0,他引:1
The position of the mid-latitude trough in the topside ionosphere is determined from electron density data of ESRO 4 during quiet solar conditions. An analysis of about 300 trough observations in the northern and southern hemispheres showed that the trough was generally seen only during the night from 19 to 05 hr LT. During this period, the invariant latitude of the minimum of the trough was found to decrease both with increasing geomagnetic disturbance represented by Kp and with increasing LT after sunset. 相似文献
19.
We have modelled the plasmaspheric density distribution for a range of solar cycle, seasonal and diurnal conditions with a magnetic flux tube dependent diffusive equilibrium model by using experimentally determined values of ionospheric parameters at 675 km as boundary conditions.Data is presented in terms of plasmaspheric H+ and He+ density contours, total flux tube content and equatorial plasma density for a range of L-values from 1.15 to 3.0. The variation of equatorial density with L-value shows good agreement with the dependence observed experimentally.The results show that the model predicts larger solar cycle and diurnal variation in equatorial plasma density than observed using whistler techniques. However, the whistler method requires a model to deduce the equatorial density and is therefore open to interpretation.Seasonal variations are rather artifical since in this general model we have not attempted to match equatorial densities for flux tubes emanating from the winter and summer hemispheres. 相似文献
20.
Extensive calculations have been made of the behaviour of He+ for situations where ion outflow occurs from the topside ionosphere. For these circumstances, steady state solutions for the He+ continuity, momentum and energy equations have been obtained self-consistently, yielding density, velocity and temperature profiles of He+ from 200 to 2000 km altitude. To model the high latitude topside ionosphere, a range of background H+O+ ionospheres was considered with variations in the H+ outflow velocity, the presence of a perpendicular electric field and different peak O+ densities. In addition, the atmospheric density of neutral helium was chosen to model typical observed winter and summer densities. From our studies we have found that: (a) The outflowing He+ has density profiles of similar shape to those of H+, for basically different reasons; (b) The effect of the perpendicular electric field differs considerably for H+ and He+. This difference stems from the fact that an electric field acts to alter significantly the O+ density at high altitudes and this, in turn, changes the H+ escape flux through the O++H charge exchange reaction. A similar situation does not occur for He+ and therefore the He+ escape flux exhibits a negligibly small change with electric field; (c) The fractional heating of He+ due to the He+O+ relative flow is not as effective in heating He+ as the H+O+ relative flow is in heating H+; (d) During magnetospheric disturbances when the N2 density at the altitude of the He+ peak (600 km) can increase by a factor as large as 50, the He+ peak density decreases only by approximately a factor of 2; and (e) The He+ escape flux over the winter pole is approximately a factor of 20 greater than the He+ escape flux over the summer pole. Consequently, on high latitude closed field lines there could be an interhemispheric He+ flux from winter to summer. 相似文献