Aktivní experimenty v kosmickém plazmatu

Přech, Lubomír

About DML-CZ | FAQ | Conditions of Use | Math Archives | Contact Us

Previous | Up | Next

Article

Aktivní experimenty v kosmickém plazmatu. (Czech) [Active experiments in cosmic plasma]. Pokroky matematiky, fyziky a astronomie, vol. 51 (2006), issue 3, pp. 239-258

Full entry |

PDF (1.5 MB) Feedback

Similar articles:

References:

[1] Parker, L. W., Murphy, B. L.: Potential buildup on an electron-emitting ionospheric satellite. J. Geophys. Res. 72 (5) (1967), 1631–1636.

[2] Laframboise, J. G., Sonmor, L. J.: Current collection by probes and electrodes in space magnetoplasmas: A review. J. Geophys. Res. 98 (A1) (1993), 337–357.

[3] Stone, N. H., Bonifazi, C.: The TSS-1R mission: Overview and scientific context. Geophys. Res. Lett. 25 (4) (1998), 409–412.

[4] Myers, N. B. et al.: A comparison of current-voltage relationships of collectors in the Earth’s ionosphere with and without electron beam emission. Geophys. Res. Lett. 16 (5) (1989), 365–368.

[5] Hess, W. N. et al.: Artificial aurora experiment: Experiment and principal results. J. Geophys. Res. 76 (25) (1971), 6067–6081.

[6] Davis, T. N. et al.: Artificial aurora experiment: Ground-based optical measurements. J. Geophys. Res. 76 (25) (1971), 6082–6092.

[7] Cambou, F. et al.: The Zarnitza rocket experiment on electron injection. In Space Research XV, p. 491, Akademie-Verlag, Berlin 1975.

[8] Winckler, J. R.: The application of artificial electron beams to magnetospheric research. Rev. Geophys. Space Phys. 18 (3) (1980), 659–682.

[9] Grandal, B.: Artificial particle beams in space plasma studies. NATO Adv. Study Inst. Ser. B: Physics, Plenum Press, New York 1982.

[10] Winckler, J. R.: Artificial electron beams as probes of the magnetosphere. J. Spacecr. Rock. 20 (3) (1983), 293–298.

[11] Neubert, T., Banks, P. M.: Recent results from studies of electron beam phenomena in space plasmas. Planet. Space Sci. 40 (2/3) (1992), 153–183.

[12] Myers, B. et al.: Vehicle charging effects during electron beam emission from the CHARGE-2 experiment. J. Spacecr. Rock. 27 (1) (1990), 25–37.

[13] Gilchrist, B. E. et al.: Electron collection enhancement arising from neutral gas jets on a charged vehicle in the ionosphere. J. Geophys. Res. 95 (A3) (1990), 2469–2475.

[14] Oberhardt, M. R. et al.: Positive spacecraft charging as measured by the shuttle potential and return electron experiment. IEEE Trans. Nucl. Sci., NS-40, (6) (1993), 1532-1541.

[15] Banks, P. M. et al.: Results from the vehicle charging and potential experiment on STS-3. J. Spacecr. Rock. 24 (2) (1986), 138–149.

[16] Sasaki, S. et al.: Neutralisation of beam-emitting spacecraft by plasma injection. J. Spacecr. Rock. 24 (3) (1987), 227–231.

[17] Sasaki, S. et al.: Gas ionization induced by a high speed plasma injection in space. Geophys. Res. Lett. 13 (5) (1986), 434–437.

[18] Katz, I. et al.: Interactions between the space experiments with particle accelerators plasma contactor and the ionospere. J. Spacecr. Rock. 31 (6) (1994), 1079–1084.

[19] Marshall, J. A. et al.: Spacelab 1 experiments on interaction of an energetic electron beam with neutral gas. J. Spacecr. Rock. 25 (5) (1988), 361–367.

[20] Sasaki, S. et al.: Ignition of beam plasma discharge in the electron beam experiment in space. Geophys. Res. Lett. 12 (10) (1985), 647–650.

[21] Neubert, T. et al.: Waves generated during electron beam emissions from the space shuttle. J. Geophys. Res. 91 (A10) (1986), 11321–11329.

[22] Bush, R. I. et al.: Electromagnetic fields from pulsed electron beam experiments in space: Spacelab-2 results. Geophys. Res. Lett. 14 (10) (1987), 1015–1018.

[23] Banks, P. M., Raitt, W. J.: Observation of electron beam structure in space experiments. J. Geophys. Res. 93 (A6) (1988), 5811–5822.

[24] Wilhelm, K., Studemann, W., Riedler, W.: Electron flux intensity distributions observed in response to particle beam emissions. Science 225 (July 13) (1984), 186–188.

[25] Burch, J. L.: Space plasma physics results from Spacelab 1. J. Spacecr. Rock. 23 (3) (1986), 331–335.

[26] Marshall, J. A. et al.: CIV experiments on Atlas-1. Geophys. Res. Lett. 20 (6) (1993), 499–502.

[27] Burch, J. L. et al.: Artificial auroras in the upper atmosphere 1. Electron beam injections. Geophys. Res. Lett. 20 (6) (1993), 491–494.

[28] Gilchrist, B. E. et al.: Enhanced electrodynamic tether currents due to electron emission from a neutral gas discharge: Results from the TSS-1R mission. Geophys. Res. Lett. 25 (4) (1998), 437–440.

[29] Thompson, D. C. et al.: The current-voltage characteristics of a large probe in low Earth orbit: TSS-1R results. Geophys. Res. Lett. 25 (4) (1998), 413–416.

[30] Iess, L. et al.: Plasma waves in the sheath of the TSS-1R satellite. Geophys. Res. Lett. 25 (4) (1998), 421–424.

[31] Winningham, J. D. et al.: Suprathermal electrons observed on the TSS-1R satellite. Geophys. Res. Lett. 25 (4) (1998), 429–432.

[32] Gerver, M. J., Hastings, D. E., Oberhardt, M. R.: Theory of plasma contactors in ground-based experiments and low Earth orbit. J. Spacecr. Rock. 27 (4) (1990), 391–402.

[33] Raitt, W. J.: Stimulating our piece of the universe: Active experiments. Rev. Geophys. Suppl., U. S. National Report to Int. Union of Geodesy and Geophysics 1991–1994 (1995), 559–564.

[34] Fischer, S.: INTERSHOCK project: Science objectives, mission overview, instrumentation and data processing. Publ. of the Astr. Inst. CSAV, Astronomical Institute of Czech. Academy of Sci., Ondrejov, Czechoslovakia 1985.

[35] Dokukin, V. S.: The APEX project scientific facility orbital complex. In Project APEX. Scientific purposes, simulation, technology and equipment of experiment (in Russian), p. 16, NAUKA, Moscow 1992.

[36] Přech, L.: Aktivní experimenty v magnetosféře Země: projekt APEX. Disertační práce, Univerzita Karlova v Praze 1995.

[37] Arcimovic, L. A. a kol.: Vývoj stacionárního plazmového motoru (SPE) a jeho užití na umělé družici “Meteor”. (v ruštině). Kosm. Issled. 12 (3) (1974), 451–468.

[38] Haerendel, G., Sagdeev, R. Z.: Artificial plasma jet in the ionosphere. Adv. Space Res. 1 (1981), 29.

[39] Němeček, Z. et al.: Artificial electron and ion beam effects: APEX experiment. J. Geophys. Res. 102 (A2) (1997), 2201–2212.

[40] Tříska, P. et al.: A subsatellite for mother-daughter active space experiments. Adv. Space Res. 10 (7) (1990), 165–168.

[41] Přech, L. et al.: Artificial ion beam effects on spacecraft potential. Adv. Space Res. 24 (8) (1999), 1027–1032.

[42] Zilavy, P. et al.: Spacecraft potential during an active experiment: a comparison of experimental results with a simple model. Ann. Geophys. 21 (4) (2003), 915–922.

[43] Přech, L. et al.: Actively produced high-energy electron bursts within the magnetosphere: the APEX project. Ann. Geophys. 20 (10) (2002), 1529–1538.

[44] Huang, C. Y. et al.: Electron acceleration by megahertz waves during OEDIPUS C. J. Geophys. Res. 106 (A2) (2001), 1835–1847.

[45] Rothkaehl, H. et al.: Remote spacecraft observations of waves excited by the pulse electron beam injected into ionosphere. Adv. Space Res. 15 (12) (1995), 25–28.

Browse
- Collections
- Titles
- Authors
- MSC

About DML-CZ

Partner of

Article

Search

Browse