Nonlinear Simulations of Jupiter's 5-Micron Hot Spots

Nonlinear Simulations of Jupiter's 5-Micron Hot Spots

Large-scale nonlinear simulations of Jupiter's 5-micron hot spots produce long-lived coherent structures that cause subsidence in local regions, explaining the low cloudiness and the dryness measured by the Galileo probe inside a hot spot. Like observed hot spots, the simulated coherent structu...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2000-09, Vol.289 (5485), p.1737-1740
Hauptverfasser: Showman, Adam P., Dowling, Timothy E.
Format: Artikel
Sprache:eng
Schlagworte:
Air pressure
Ammonia
Astronomy
Brunt Vaisala frequency
Climate
Clouds
Condensation
Earth, ocean, space
Equatorial regions
Exact sciences and technology
Extraterrestrial Environment
Hemispheres
Hydrogen Sulfide
Jupiter
Jupiter (Planet)
Lunar And Planetary Science And Exploration
Natural history
Neutral atmospheres
Observations
Planetary probes
Planetary, asteroid, and satellite characteristics and properties
Planets, their satellites and rings. Asteroids
Plumes
Pressure
Simulation
Solar system
Space life sciences
Space probes
Temperature
Water
Water pressure
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Beschreibung
Zusammenfassung:Large-scale nonlinear simulations of Jupiter's 5-micron hot spots produce long-lived coherent structures that cause subsidence in local regions, explaining the low cloudiness and the dryness measured by the Galileo probe inside a hot spot. Like observed hot spots, the simulated coherent structures are equatorially confined, have periodic spacing, propagate west relative to the flow, are generally confined to one hemisphere, and have an anticyclonic gyre on their equatorward side. The southern edge of the simulated hot spots develops vertical shear of up to 70 meters per second in the eastward wind, which can explain the results of the Galileo probe Doppler wind experiment.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.289.5485.1737