Radio Frequency Signals in Jupiter's Atmosphere

Radio Frequency Signals in Jupiter's Atmosphere

During the Galileo probe's descent through Jupiter's atmosphere, under the ionosphere, the lightning and radio emission detector measured radio frequency signals at levels significantly above the probe's electromagnetic noise. The signal strengths at 3 and 15 kilohertz were relatively...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 1996-05, Vol.272 (5263), p.858-860
Hauptverfasser: Lanzerotti, L. J., Rinnert, K., Dehmel, G., Gliem, F. O., Krider, E. P., Uman, M. A., Bach, J.
Format: Artikel
Sprache:eng
Schlagworte:
Amplitude
Astronomical and space-research instrumentation
Astronomy
Atmosphere
Atmospherics
Earth, ocean, space
Electromagnetic interference
Exact sciences and technology
Field Tests
Frequencies
Fundamental astronomy and astrophysics. Instrumentation, techniques, and astronomical observations
Galileo Probes Jupiter's Atmosphere
Intervals
Jovian atmosphere
Jupiter
Jupiter (Planet)
Jupiter probes
Lightning
Lunar, planetary, and deep-space probes
Magnetic fields
Neutral atmospheres
Observations
Opacity
Planetary atmospheres
Planetary, asteroid, and satellite characteristics and properties
Planets
Planets, their satellites and rings. Asteroids
Radio
Radio frequencies
Signal detection
Solar system
Space probes
Spacecraft
Waveforms
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Beschreibung
Zusammenfassung:During the Galileo probe's descent through Jupiter's atmosphere, under the ionosphere, the lightning and radio emission detector measured radio frequency signals at levels significantly above the probe's electromagnetic noise. The signal strengths at 3 and 15 kilohertz were relatively large at the beginning of the descent, decreased with depth to a pressure level of about 5 bars, and then increased slowly until the end of the mission. The 15-kilohertz signals show arrival direction anisotropies. Measurements of radio frequency wave forms show that the probe passed through an atmospheric region that did not support lightning within at least 100 kilometers and more likely a few thousand kilometers of the descent trajectory. The apparent opacity of the jovian atmosphere increases sharply at pressures greater than about 4 bars.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.272.5263.858