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Eiges P. E. Zastenker G. N. Safrankova J. Nemecek Z. Eismont N. A. 《Cosmic Research》2001,39(5):432-438
Based on simultaneous measurements of ion fluxes made onboard the closely separated satellites Interball-1and Magion-4, the propagation velocity of middle-scale plasma structures in the Earth's foreshock relative to the solar wind flow is estimated. The derived value of this velocity allows these structures to be identified as a fast magnetosonic wave propagating upstream of the solar wind inflowing the Earth's bow shock. An evaluation is also made of the correlation length of these disturbances in the plane perpendicular to the Sun–Earth line. This length is approximately equal to 2R
E. 相似文献
2.
L. Prech Z. Nemecek J.
afrnkov J.
imunek V. Truhlík N. M. Shutte 《Advances in Space Research (includes Cospar's Information Bulletin, Space Research Today)》1995,15(12):33-36
The paper is based on the electron and ion energy spectra measurement on board the main spacecraft of the APEX mission. During the active phase of the experiment an intense electron beam was emitted from the main satellite. The basic cycle of the electron injection is formed by current pulses of different frequencies, duration and intensity. The spacecraft potential changes due to the gun operation were compensated by a low energy Xe plasma generator. The data show that the response of the environment to the beam emission depends not only on injection parameters but on the spacecraft position and orientation with respect to the magnetic field as well. The typical response is an increase of the intensity of the low energy (less than 1 keV) electrons in all directions. In addition, strong field aligned fluxes of electrons and/or ions are observed with energies below the gun energy. An attempt to classify different types of response and to find possible mechanisms which can explain the observed phenomena is made in the present paper. 相似文献
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4.
P. Eiges G. Zastenker M. Nozdrachev N. Rybyeva J. Safrankova Z. Nemecek 《Advances in Space Research (includes Cospar's Information Bulletin, Space Research Today)》2002,30(12):2725-2729
High time resolution data obtained by VDP and FM-31 instruments onboard INTERBALL-1 spacecraft were used to study the small-scale correlation between solar wind ion flux and magnetic field magnitude in the Earth's foreshock. Correlated quasi-harmonic structures were found simultaneously in ion flux and magnetic field data. Statistical analysis of these structures was done and a summary of obtained results is presented. Multipoint observations by INTERBALL-1 and MAGION-4 were used to estimate spatial correlation of small quasi-harmonic structures. 相似文献
5.
G. N. Zastenker J. Safrankova Z. Nemecek L. Prech I. Cermak I. Vaverka A. Komarek J. Voita L. S. Chesalin B. T. Karimov Yu. N. Agafonov N. L. Borodkova E. A. Gavrilova T. I. Gagua I. T. Gagua P. A. Dalin A. V. D’yachkov I. V. Koloskova A. V. Leibov N. P. Semena V. V. Chernov Ya. I. Markov E. E. Ryazanova M. O. Ryazanrtseva N. N. Shevyrev V. V. Chrapchenkov O. M. Chugunova A. S. Yurasov 《Cosmic Research》2013,51(2):78-89
Design of the plasma spectrometer BMSW (Fast Monitor of the Solar Wind, possessing high temporal resolution) is described in the paper, as well as its characteristics and modes of operation. Some examples of measurements of various properties of the solar wind, made with this instrument installed onboard the high-apogee satellite Spektr-R, are presented. 相似文献
6.
G. N. Zastenker I. V. Koloskova M. O. Riazantseva A. S. Yurasov J. Safrankova Z. Nemecek L. Prech P. Cagas 《Cosmic Research》2014,52(1):25-36
This paper describes the results of studying the helium component of the solar-wind ion-flux measurement by the BMSW instrument on the Spektr-R satellite with a time resolution of 3 s. In contrast to most previous works that presented values averaged over large (hourly average or daily average) intervals, we have shown that the relative helium-ion abundance in the solar wind experiences considerable (by a few percent and even 10%) variations on such short intervals as 10 seconds or even several seconds. 相似文献
7.
S. Savin L. Zelenyi N. Maynard I. Sandahl H. Kawano C. T. Russell S. Romanov E. Amata L. Avanov J. Blecki J. Buechner G. Consolini G. Gustafsson S. Klimov F. Marcucci Z. Nemecek B. Nikutowski J. Pickett J. L. Rauch J. Safrankova A. Skalsky V. Smirnov K. Stasiewicz P. Song J. G. Trotignon Yu. Yermolaev 《Advances in Space Research (includes Cospar's Information Bulletin, Space Research Today)》2002,30(12):2821-2830
Multi-spacecraft tracing of the high latitude magnetopause (MP) and boundary layers and Interball-1 statistics indicate that:
- 1. (a) The turbulent boundary layer (TBL) is a persistent feature in the region of the cusp and ‘sash’, a noticeable part of the disturbances weakly depends on the interplanetary magnetic field By component; TBL is a major site for magnetosheath (MSH) plasma penetration inside the magnetosphere through percolation and local reconnection.
- 2. (b) The TBL disturbances are mainly inherent with the characteristic kinked double-slope spectra and, most probably, 3-wave cascading. The bi-spectral phase coupling indicates self-organization of the TBL as the entire region with features of the non-equilibrium multi-scale and multi-phase system in the near-critical state.
- 3. (c) We've found the different outer cusp topologies in summer/winter periods: the summer cusp throat is open for the decelerated MSH flows, the winter one is closed by the distant MP with a large-scale (several Re) diamagnetic ‘plasma ball’ inside the MP; the ‘ball’ is filled from MSH through patchy merging rather than large-scale reconnection.
- 4. (d) A mechanism for the energy release and mass inflow is the local TBL reconnection, which operates at the larger scales for the average anti-parallel fields and at the smaller scales for the nonlinear fluctuating fields; the latter is operative throughout the TBL. The remote from TBL anti-parallel reconnection seems to happen independently.
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相似文献
8.
Aircraft maintenance has, since its conception, relied primarily on two methods of fault detection and isolation: 1) in-flight observation and reporting by flight personnel 2) ground operation or testing of airborne systems and equipment. Both methods, even when combined to the optimum, are not always sufficient to pinpoint the exact cause of trouble or locate a defective component. A third method, which analyzes airborne system's performance through various techniques of multiparameter sampling, has recently come into the picture and is showing significant promise for advancing the present state-of-the-art in aircraft maintenance. Systems utilizing this technique are discussed and examples of their benefits cited. These benefits not only encompass detection and isolation of defective units or components, but also include predicting impending malfunctions. 相似文献
9.
N. N. Shevyrev G. N. Zastenker J. Safrankova Z. Nemecek M. Gaiosh J. D. Richardson 《Cosmic Research》2002,40(4):335-346
We present the results of experimental studies of high frequency (with periods of seconds and tens of seconds) and low frequency (with periods of minutes and tens of minutes) large variations of the ion flux and magnetic field magnitude in the magnetosheath. It is shown that, on average, the relative amplitudes of these variations are approximately two times higher than similar values characteristic for the undisturbed solar wind. The averaged spatial profile of these values and their variations across the magnetosheath is obtained, as are the dependencies of normalized plasma fluxes and their variations on the place of entrance of a given plasma element into the magnetosheath. Using one particular example, a good coincidence between the time profiles of ion fluxes measured aboard two spacecraft separated by a distance of 10R
E along the magnetosheath is demonstrated. 相似文献
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