A. Adriani, A. Coradini, G. Filacchione, J.I. Lunine, A. Bini, C. Pasqui, L. Calamai, F. Colosimo, B.M. Dinelli, D. Grassi, G. Magni, M.L. Moriconi, R. Orosei, JIRAM, the image spectrometer in the near-infrared on board the Juno mission to Jupiter. Astrobiology 8, 613–622 (2008) ArticleADS Google Scholar
Y. Alibert, C. Mordasini, W. Benz, C. Winisdoerffer, Models of giant planet formation with migration and disc evolution. Astron. Astrophys. 434, 343–353 (2005) ArticleADS Google Scholar
S.K. Atreya, M.H. Wong, T.C. Owen, P.R. Mahaffy, H.B. Niemann, I. de Pater, P. Drossart, T. Encrenaz, A comparison of the atmospheres of Jupiter and Saturn: deep atmospheric composition, cloud structure, vertical mixing, and origin. Planet. Space Sci. 47, 1243–1262 (1999) ArticleADS Google Scholar
F. Bagenal, A. Adriani, F. Allegrini et al., Magnetospheric science objectives of the Juno mission. Space Sci. Rev. (2017). doi:10.1007/s11214-014-0036-8 Google Scholar
I. Baraffe, G. Chabrier, T. Barman, Structure and evolution of super-Earth to super-Jupiter exoplanets. I. Heavy element enrichment in the interior. Astron. Astrophys. 482, 315–332 (2008) ArticleADS Google Scholar
H.N. Becker, J.W. Alexander, A. Adriani et al., The Juno Radiation Monitoring (RM) investigation. Space Sci. Rev. (2017). doi:10.1007/s11214-017-0345-9 Google Scholar
B. Bonfond, D. Grodent, J.-C. Gérard, T. Stallard, J.T. Clarke, M. Yoneda, A. Radioti, J. Gustin, Auroral evidence of Io’s control over the magnetosphere of Jupiter. Geophys. Res. Lett. 39, 1105 (2012) ArticleADS Google Scholar
A.P. Boss, Evolution of the solar nebula. IV. Giant gaseous protoplanet formation. Astrophys. J. 503, 923–937 (1998) ArticleADS Google Scholar
F.H. Busse, A simple model of convection in the Jovian atmosphere. Icarus 29, 255–260 (1976) ArticleADS Google Scholar
J.E. Chambers, G.W. Wetherill, Making the terrestrial planets: N-body integrations of planetary embryos in three dimensions. Icarus 136, 304–312 (1998) ArticleADS Google Scholar
J.E.P. Connerney, M.H. Acuna, N.F. Ness, Modeling the Jovian current sheet and inner magnetosphere. J. Geophys. Res. 86, 8370–8384 (1981) ArticleADS Google Scholar
J.E.P. Connerney, M.H. Açuna, N.F. Ness, T. Satoh, New models of Jupiter’s magnetic field constrained by the Io Flux Tube footprint. J. Geophys. Res. 103, 11929–11939 (1998) ArticleADS Google Scholar
B.J. Conrath, D. Gautier, Saturn helium abundance: a reanalysis of Voyager measurements. Icarus 144, 124–134 (2000) ArticleADS Google Scholar
R.W. Ebert, F. Bagenal, D. McComas, C. Fowler, A survey of solar wind conditions at 5 AU: a tool for interpreting solar wind-magnetosphere interactions at Jupiter. Front. Astron. Space Sci. 1, 4 (2014) ArticleADS Google Scholar
J.J. Fortney, W.B. Hubbard, Phase separation in giant planets: inhomogeneous evolution of Saturn. Icarus 164, 228–243 (2003) ArticleADS Google Scholar
J.J. Fortney, W.B. Hubbard, Effect of helium phase separation on the evolution of extrasolar giant planets. Astrophys. J. 608, 1039–1049 (2004) ArticleADS Google Scholar
J.J. Fortney, M. Ikoma, N. Nettleman, T. Guillot, M.S. Marley, Self-consistent model atmospheres and the cooling of the solar system’s giant planets. Astrophys. J. 729, 32 (2011), 14pp. ArticleADS Google Scholar
M. French, A. Becker, W. Lorenzen, N. Nettelmann, M. Bethkenhagen, J. Wicht, R. Redmer, Ab initio simulations for material properties along the Juptier adiabat. Astrophys. J. Suppl. 202, 5 (2012). doi:10.1088/0067-0049/202/1/5 ArticleADS Google Scholar
D. Gautier, F. Hersant, O. Mousis, J.I. Lunine, Enrichments in volatiles in Jupiter: a new interpretation of the Galileo measurements. Astrophys. J. Lett. 550, L227–L230 (2001) (Erratum 559, L183) ArticleADS Google Scholar
P.J. Gierasch, A.P. Ingersoll, D. Banfield, S.P. Ewald, P. Helfenstein, A. Simon-Miller, A. Vasavada, H.H. Breneman, D.A. Senske (Galileo Imaging Team), Observation of moist convection in Jupiter’s atmosphere. Nature 403, 628–630 (2000) ArticleADS Google Scholar
G.R. Gladstone, S.C. Persyn, J.S. Eterno et al., The ultraviolet spectrograph on NASA’s Juno mission. Space Sci. Rev. (2014). doi:10.1007/s11214-014-0040-z Google Scholar
R.S. Grammier, A look inside the Juno mission to Jupiter. IEEE Aerospace Conference, paper #1582 (2009)
D. Grodent, J.T. Clarke, J. Kim, J.H. Waite Jr., S.W.H. Cowley, Jupiter’s main auroral oval observed with HST-STIS. J. Geophys. Res. 108, 1389 (2003) Article Google Scholar
S.M. Guertin, G.R. Allen, D.J. Sheldon, Programmatic Impact of SDRAM SEFI, 16–20 July 2012, IEEE Radiation Effects Data Workshop (2012). doi:10.1109/REDW.2012.6353722 Book Google Scholar
T. Guillot, A comparison of the interiors of Jupiter and Saturn. Planet. Space Sci. 47, 1175–1182 (1999) ArticleADS Google Scholar
T. Guillot, The interiors of giant planets: models and outstanding questions. Annu. Rev. Earth Planet. Sci. 33, 493–530 (2005) ArticleADS Google Scholar
T. Guillot, D. Gautier, W.B. Hubbard, New constraints on the composition of Jupiter from Galileo measurements and interior models. Icarus 130, 534–539 (1997) ArticleADS Google Scholar
T. Guillot, D.J. Stevenson, W.B. Hubbard, D. Saumon, The interior of Jupiter, in Jupiter, ed. by F. Bagenal et al. (Cambridge University Press, Cambridge, 2004), pp. 35–57, Chap. 3 Google Scholar
P. Helled, M. Podolak, A. Kovetz, Planetesimal capture in the disk instability model. Icarus 185, 64–71 (2006) ArticleADS Google Scholar
F. Hersant, D. Gautier, F. Huré, A two-dimensional model for the primordial nebula constrained by D/H measurements in the Solar System: implications for the formation of giant planets. Astrophys. J. 554, 391–407 (2001) ArticleADS Google Scholar
F. Hersant, D. Gautier, J.I. Lunine, Enrichment in volatiles in the giant planets of the Solar System. Planet. Space Sci. 52, 623–641 (2004) ArticleADS Google Scholar
W.B. Hubbard, Thermal structure of Jupiter. Astrophys. J. 152, 745–754 (1968) ArticleADS Google Scholar
W.B. Hubbard, The Jovian surface condition and cooling rate. Icarus 30, 305–310 (1977) ArticleADS Google Scholar
W.B. Hubbard, Gravitational signature of Jupiter’s deep zonal flows. Icarus 137, 357–359 (1999) ArticleADS Google Scholar
A.P. Ingersoll, D. Pollard, Motion in the interiors and atmospheres of Jupiter and Saturn—scale analysis, anelastic equations, barotropic stability criterion. Icarus 52, 62–80 (1982) ArticleADS Google Scholar
M.E. Janssen, J.E. Oswald, S.T. Brown, S. Gulkis, S.M. Levin, S.J. Bolton, M.D. Allison, S.K. Atreya, D. Gautier, A.P. Ingersoll, J.I. Lunine, G.S. Orton, T.C. Owen, P.G. Steffes, V. Adumitroaie, A. Belloti, L.A. Jewell, C. Li, L. Li, F.A. Oyafuso, D. Santos-Costa, E. Sarkissian, R. Williamson, J.K. Arballo, A. Kityakara, A. Ulloa-Severino, J.C. Chen, F.W. Maiwald, A.S. Sahakian, P.J. Pingree, K.A. Lee, A.S. Mazer, R. Redick, R.E. Hodges, R.C. Hughes, G. Bedrosian, D.E. Dawson, W.A. Hatch, D.S. Russell, N.F. Chamberlain, M.S. Zawadski, B. Khayatian, B.R. Franklin, H.A. Conley, J.G. Kempenaar, M.S. Loo, E.T. Sunada, V. Vorperion, C.C. Wang, MWR microwave radiometer for the Juno mission to Jupiter. Space Sci. Rev. (2017). doi:10.1007/s11214-017-0349-5 Google Scholar
S.P. Joy, M.G. Kivelson, R.J. Walker, K.K. Khurana, C.T. Russell, T. Ogino, Probabilistic models of the Jovian magnetopause and bow shock locations. J. Geophys. Res. 107, A101309 (2002). doi:10.1029/2001JA009146 ArticleADS Google Scholar
S. Kayali, W. McAlpine, H. Becker, L. Scheick, in Juno Radiation Design and Implementation, IEEE Aerospace Conf., 3–10 March 2012 (2012), 3–10. doi:10.1109/AERO.2012.6187013 Google Scholar
J. Leconte, G. Chabrier, A new vision of giant planet interiors: impact of double diffusive convection. Astron. Astrophys. 540, A20 (2012), 13 pp ArticleADS Google Scholar
J. Lewis, Juno spacecraft operations lessons learned for early cruise mission phases. IEEE Aerospace Conference (2014)
G.F. Lindal, G.E. Wood, G.S. Levy, J.D. Anderson, D.N. Sweetnam, H.B. Hotz, B.J. Buckles, D.P. Holmes, P.E. Doms, V.R. Eshleman, G.L. Tyler, T.A. Croft, The atmosphere of Jupiter—an analysis of the Voyager radio occultation measurements. J. Geophys. Res. 86, 8721–8727 (1981) ArticleADS Google Scholar
K. Lodders, Jupiter formed with more tar than ice. Astrophys. J. 6111, 587–597 (2004) ArticleADS Google Scholar
F. Low, Infrared observations of Venus, Jupiter and Saturn at \(\lambda 20\mu\). Astron. J. 71, 391 (1966) ArticleADS Google Scholar
M. Lozovsky, R. Helled, E.D. Rosenberg, P. Bodenheimer, Jupiter’s formation and its primordial internal structure. Astrophys. J. 836, 1–31 (2017). doi:10.3847/1538-4357/836/2/227 Article Google Scholar
J.I. Lunine, D.M. Hunten, Moist convection and the abundance of water in the troposphere of Jupiter. Icarus 69, 566–570 (1987) ArticleADS Google Scholar
B.H. Mauk, D.K. Haggerty, S.E. Jaskulek et al., The Jupiter energetic particle detector instrument (JEDI) investigation for the Juno mission. Space Sci. Rev. (2013). doi:10.1007/s11214-013-0025-3 Google Scholar
L. Mayer, T. Quinn, J. Wadsley, J. Stadel, Formation of giant planets by fragmentation of protoplanetary disks. Science 298, 1756–1759 (2002) ArticleADS Google Scholar
D.J. McComas, N. Alexander, F. Allegrini et al., The Jovian Auroral Distributions Experiment (JADE) on the Juno mission to Jupiter. Space Sci. Rev. (2013). doi:10.1007/s11214-013-9990-9 Google Scholar
B. Militzer, W.B. Hubbard, J. Vorberger, I. Tamblyn, S.A. Bonev, Astrophys. J. 688, L45 (2008) ArticleADS Google Scholar
H. Mizuno, Formation of the giant planets. Prog. Theor. Phys. 64, 544–557 (1980) ArticleADS Google Scholar
O. Mousis, J.I. Lunine, N. Madhusudhan, T.V. Johnson, Nebular water depletion as the cause of Jupiter’s low oxygen abundance. Astrophys. J. Lett. 751, L7 (2012). doi:10.1088/2041-8205/751/1/L7 ArticleADS Google Scholar
N. Nettelmann, B. Holst, A. Kietzmann, M. French, R. Redmer, Ab initio equation of state data for hydrogen, helium, and water and the internal structure of Jupiter. Astrophys. J. 683, 1217–1228 (2008) ArticleADS Google Scholar
R. Nybakken, The Juno mission to Jupiter—a pre-launch update. IEEE Aerospace Conference paper #1179 (2011)
R. Nybakken, The Juno mission to Jupiter—launch campaign and early cruise report. IEEE Aerospace Conference (2012)
T. Owen, Th. Encrenaz, Element abundances and isotopic ratios in the giant planets and Titan. Space Sci. Rev. 106, 121–138 (2003) ArticleADS Google Scholar
T. Owen, P. Mahaffy, H.B. Niemann, S.K. Atreya, T.M. Donahue, A. Bar-Nun, I. de Pater, A low temperature origin for the planetesimals that formed Jupiter. Nature 402, 269–270 (1999) ArticleADS Google Scholar
J.B. Pollack, O. Hubickyi, P. Bodenheimer, J.J. Lissauer, M. Podolak, Y. Greenzweig, Formation of the giant planets by concurrent accretion of solids and gas. Icarus 124, 62–85 (1996a) ArticleADS Google Scholar
J.B. Pollack, O. Hubickyj, P. Bodenheimer, J.J. Lissauer, M. Podolak, Y. Greenzweig, A review of hydrogen, carbon, nitrogen, oxygen, sulphur, and chlorine stable isotope enrichment among gaseous molecules. Icarus 124, 62–85 (1996b) ArticleADS Google Scholar
D. Saumon, T. Guillot, Shock compression of deuterium and the interiors of Jupiter and Saturn. Astrophys. J. 609, 1170–1180 (2004) ArticleADS Google Scholar
D. Saumon, W.B. Hubbard, A. Burrows, T. Guillot, J.I. Lunine, G. Chabrier, A theory of extrasolar giant planets. Astrophys. J. 460, 993–1018 (1996) ArticleADS Google Scholar
A. Seiff, D.B. Kirk, T.C.D. Knight, R.E. Young, J.D. Mihalov, L.A. Young, F.S. Milos, G. Schubert, R.C. Blanchard, D. Atkinson, Thermal structure of Jupiter’s atmosphere near the edge of a 5-μm hot spot in the North equatorial belt. J. Geophys. Res. 103, 22857–22890 (1998) ArticleADS Google Scholar
A.P. Showman, T.E. Dowling, Nonlinear simulations of Jupiter’s 5-micron hot spots. Science 289, 1737–1740 (2000) ADS Google Scholar
S.K. Stephens, The Juno mission to Jupiter: lessons from cruise and plans for orbital operations and science return. IEEE Aerospace Conference, paper # 2150 (2015)
D.J. Stevenson, Thermodynamics and phase separation of dense fully ionized hydrogen-helium fluid mixtures. Phys. Rev. B 12, 3999–4007 (1975) ArticleADS Google Scholar
D.J. Stevenson, E.E. Salpeter, The dynamics and helium distribution in hydrogen-helium planets. Astrophys. J. Suppl. Ser. 35, 239–261 (1977) ArticleADS Google Scholar
U. Von Zahn, D.M. Hunten, G. Lehmacher, Helium in Jupiter’s atmosphere: results from the Galileo probe helium interferometer experiment. J. Geophys. Res. 103, 22815–22829 (1998) ArticleADS Google Scholar
H.F. Wilson, B. Militzer, Solubility of water ice in metallic hydrogen: consequences for core erosion in gas giant planets. Astrophys. J. 745, 54 (2011) ArticleADS Google Scholar
H.F. Wilson, B. Militzer, Rocky core solubility in Jupiter and giant exoplanets. Phys. Rev. Lett. 108, 111101 (2012) ArticleADS Google Scholar
M.H. Wong, P.R. Mahaffy, S.K. Atreya, H.B. Niemann, T.C. Owen, Updated Galileo probe mass spectrometer measurements of carbon, oxygen, nitrogen, and sulfur on Jupiter. Icarus 171, 153–170 (2004) ArticleADS Google Scholar
M.H. Wong, J.I. Lunine, S.K. Atreya, T. Johnson, P.R. Mahaffy, T.C. Owen, T. Encrenaz, Oxygen and other volatiles in the giant planets and their satellites. Rev. Mineral. Geochem. 68, 219–246 (2008) Article Google Scholar
G. Wuchterl, T. Guillot, J.J. Lissauer, Giant planet formation, in Protostars and Planets IV, ed. by V. Mannings, A.P. Boss, S.S. Russel (University of Arizona Press, Tucson, 2000), pp. 1081–1109 Google Scholar