Add to ORKGThe radiative seasonal model described by Bezard and Gautier for the case of Saturn was adapted to Jupiter. That the atmosphere is radiatively controlled above the 500 mb pressure level and that the temperature at the radiative-convective boundary level is constant for all latitudes is assumed. An internal heat source and absorption by methane and aerosols contribute to atmospheric heating. Absorption by aerosols was adjusted to give a planetary Bond albedo equal to 0.343. Despite Jupiter's low obliquity, the model predicts seasonal variations of temperature of several degrees for the 1 mb pressure level at mid-latitude regions
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
Voyager flyby observations have yielded the first detailed maps of wind and temperature fields in th...
Seasonal variability of the temperature structure of Uranus is modeled for all latitudes in the .000...
Two-dimensional, radiative-convective-dynamical models of the visible atmospheres of Jupiter and Ura...
In this paper the two model of Jupiter’s atmosphere, vi., adiabatic and isothermal, have been consid...
We developed a line-by-line heating and cooling rate model for the stratosphere of Jupiter, based on...
We developed a line-by-line heating and cooling rate model for the stratosphere of Jupiter, based on...
Jupiter’s obliquity and eccentricity drive the seasonal forcing on its atmosphere. The seasonal vari...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceJupiter’s obliquity and eccentricity drive the seasonal forcing on its atmosph...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
Voyager flyby observations have yielded the first detailed maps of wind and temperature fields in th...
Seasonal variability of the temperature structure of Uranus is modeled for all latitudes in the .000...
Two-dimensional, radiative-convective-dynamical models of the visible atmospheres of Jupiter and Ura...
In this paper the two model of Jupiter’s atmosphere, vi., adiabatic and isothermal, have been consid...
We developed a line-by-line heating and cooling rate model for the stratosphere of Jupiter, based on...
We developed a line-by-line heating and cooling rate model for the stratosphere of Jupiter, based on...
Jupiter’s obliquity and eccentricity drive the seasonal forcing on its atmosphere. The seasonal vari...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceJupiter’s obliquity and eccentricity drive the seasonal forcing on its atmosph...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
International audienceWe present a two-dimensional radiative-dynamical model of the combined stratos...
Voyager flyby observations have yielded the first detailed maps of wind and temperature fields in th...