Jupiter's Temperature Structure: A Reassessment of the Voyager Radio Occultation Measurements

The thermal structure of planetary atmospheres is an essential input for predicting and retrieving the distribution of gases and aerosols, as well as the bulk chemical abundances. In the case of Jupiter, the temperature at a reference level—generally taken at 1 bar—serves as the anchor in models used to derive the planet’s interior structure and composition. Most models assume the temperature measured by the Galileo probe. However, those data correspond to a single location, an unusually clear, dry region, affected by local atmospheric dynamics. On the other hand, the Voyager radio occultation observations cover a wider range of latitudes, longitudes, and times. The Voyager retrievals were based on atmospheric composition and radio refractivity data that require updating and were never properly tabulated; the few existing tabulations are incomplete and ambiguous. Here we present a systematic electronic digitization of all available temperature profiles from Voyager, followed by their reanalysis, employing currently accepted values of the abundances and radio refractivities of atmospheric species. We find the corrected temperature at the 1 bar level to be up to 4 K greater than the previously published values, i.e., 170.3 ± 3.8 K at 12°S (Voyager 1 ingress) and 167.3 ± 3.8 K at 0°N (Voyager 1 egress). This is to be compared with the Galileo probe value of 166.1 ± 0.8 K at the edge of an unusual feature at 6.°57N. Altogether, this suggests that Jupiter’s tropospheric temperatures may vary spatially by up to 7 K between 7°N and 12°S.

[1]  Radio Science Techniques for Deep Space Exploration , 2022 .

[2]  T. Guillot,et al.  Jupiter's inhomogeneous envelope , 2022, Astronomy & Astrophysics.

[3]  D. Stevenson Jupiter's Interior as Revealed by Juno , 2020, Annual Review of Earth and Planetary Sciences.

[4]  Shannon T. Brown,et al.  The water abundance in Jupiter’s equatorial zone , 2020, Nature Astronomy.

[5]  J. H. In,et al.  Deep Atmosphere Composition, Structure, Origin, and Exploration, with Particular Focus on Critical in situ Science at the Icy Giants , 2020, Space Science Reviews.

[6]  G. Orton,et al.  Jupiter's auroral-related stratospheric heating and chemistry III: Abundances of C2H4, CH3C2H, C4H2 and C6H6 from Voyager-IRIS and Cassini-CIRS , 2019, Icarus.

[7]  T. Guillot,et al.  A suppression of differential rotation in Jupiter’s deep interior , 2018, Nature.

[8]  Yi Fu,et al.  Homocysteine directly interacts and activates the angiotensin II type I receptor to aggravate vascular injury , 2018, Nature Communications.

[9]  G. Orton,et al.  Hydrogen Dimers in Giant-planet Infrared Spectra , 2017, 1712.02813.

[10]  T. Owen,et al.  Jupiter’s interior and deep atmosphere: The initial pole-to-pole passes with the Juno spacecraft , 2017, Science.

[11]  G. Orton,et al.  Jupiter's Para-H2 Distribution from SOFIA/FORCAST and Voyager/IRIS 17-37 µm Spectroscopy , 2016, 1610.01304.

[12]  T. Encrenaz,et al.  Mid-infrared mapping of Jupiter’s temperatures, aerosol opacity and chemical distributions with IRTF/TEXES , 2016, 1606.05498.

[13]  G. Orton,et al.  Phosphine on Jupiter and Saturn from Cassini/CIRS , 2009 .

[14]  P. Irwin Giant Planets of Our Solar System: Atmospheres, Composition, and Structure , 2009 .

[15]  S. Calcutt,et al.  The NEMESIS planetary atmosphere radiative transfer and retrieval tool , 2008 .

[16]  T. Encrenaz,et al.  Compositional constraints on giant planet formation , 2006 .

[17]  R. Beebe Jupiter: The Planet, Satellites and Magnetosphere , 2005 .

[18]  T. Owen,et al.  Updated Galileo probe mass spectrometer measurements of carbon, oxygen, nitrogen, and sulfur on Jupiter , 2004 .

[19]  P. Steffes,et al.  Laboratory measurements of the Ka-band (7.5 mm to 9.2 mm) opacity of phosphine (PH3) and ammonia (NH3) under simulated conditions for the Cassini-Saturn encounter , 2002 .

[20]  J. A. Magalhāes,et al.  The Stratification of Jupiter's Troposphere at the Galileo Probe Entry Site , 2000 .

[21]  T. Dowling,et al.  Nonlinear simulations of Jupiter's 5-micron hot spots. , 2000, Science.

[22]  D. Gautier,et al.  Saturn Helium Abundance: A Reanalysis of Voyager Measurements , 2000 .

[23]  Imke de Pater,et al.  A low-temperature origin for the planetesimals that formed Jupiter , 1999, Nature.

[24]  P. Gierasch,et al.  Thermal Structure and Para Hydrogen Fraction on the Outer Planets from Voyager IRIS Measurements , 1998 .

[25]  G. F. Lindal,et al.  The atmosphere of Neptune : an analysis of radio occultation data acquired with Voyager 2 , 1992 .

[26]  Y. Yung Atmospheres and Ionospheres of the Outer Planets and Their Satellites [Book Review] , 1987 .

[27]  Sushil K. Atreya,et al.  Book-Review - Atmospheres and Ionospheres of the Outer Planets and Their Satellites , 1986 .

[28]  Henry B. Hotz,et al.  The atmosphere of Titan: An analysis of the Voyager 1 radio occultation measurements , 1981 .

[29]  G. E. Wood,et al.  Radio Science with Voyager at Jupiter: Initial Voyager 2 Results and a Voyager 1 Measure of the Io Torus , 1979, Science.

[30]  S. Collins,et al.  Discovery of Currently Active Extraterrestrial Volcanism , 1979, Science.

[31]  V. Eshleman The radio occultation method for the study of planetary atmospheres , 1973 .

[32]  A. Newell,et al.  Absolute Determination of Refractive Indices of Gases at 47.7 Gigahertz , 1965 .

[33]  L. Essen The Refractive Indices of Water Vapour, Air, Oxygen, Nitrogen, Hydrogen, Deuterium and Helium , 1953 .

[34]  L. Lara,et al.  Photochemistry of Planetary Atmospheres , 2002 .

[35]  Cesare Barbieri,et al.  The three Galileos : the man, the spacecraft, the telescope : proceedings of the conference held in Padova, Italy on January 7-10, 1997 , 1997 .

[36]  James L. Elliot,et al.  Stellar Occultation Studies of the Solar System , 1979 .