S. K. Atreya, A comparison of the atmospheres of Jupiter and Saturn: deep atmospheric composition, cloud structure, vertical mixing, and origin, Planet. Space Sci, vol.47, pp.1243-1262, 1999.

J. Aurnou, Convective heat transfer and the pattern of thermal emission on the gas giants, Geophysical Journal International, vol.173, pp.793-801, 2008.

E. Bailey and D. J. Stevenson, Modeling Ice Giant Interiors Using Constraints on the H 2 -H 2 O Critical Curve, AGU Fall Meeting Abstracts, pp.31-34, 2015.

E. Bali, A. Audétat, and H. Keppler, Water and hydrogen are immiscible in Earth's mantle, Nature, vol.495, p.220, 2013.

S. J. Bolton, Jupiter's interior and deep atmosphere: The initial pole-to-pole passes with the Juno spacecraft, Science, vol.356, pp.821-825, 2017.

S. Brown, Prevalent lightning sferics at 600 megahertz near Jupiter's poles". In: Nature 558, vol.7708, pp.87-90, 2018.

H. Cao and D. J. Stevenson, Zonal flow magnetic field interaction in the semi-conducting region of giant planets, Icarus 296, pp.59-72, 2017.

C. Cavazzoni, Superionic and Metallic States of Water and Ammonia at Giant Planet Conditions, Science, vol.283, p.44, 1999.

B. J. Conrath and P. J. Gierasch, Global variation of the para hydrogen fraction in Jupiter's atmosphere and implications for dynamics on the outer planets, Icarus, vol.57, pp.184-204, 1984.

I. Pater, Peering through Jupiter's clouds with radio spectral imaging, Science 352, vol.6290, pp.1198-1201, 2016.

T. E. Dowling, The Explicit Planetary Isentropic-Coordinate (EPIC) Atmospheric Model, Icarus, vol.132, pp.221-238, 1998.

L. N. Fletcher, Saturn's tropospheric composition and clouds from Cassini/VIMS 4.6-5.1 µm nightside spectroscopy, Icarus, vol.214, pp.510-533, 2011.

L. N. Fletcher, Seasonal variability of Saturn's tropospheric temperatures, winds and para-H 2 from Cassini far-IR spectroscopy, Icarus, vol.264, pp.137-159, 2016.

L. N. Fletcher, How well do we understand the belt/zone circulation of Giant Planet atmospheres, In: arXiv e-prints, 2019.

T. Fouchet, E. Lellouch, and H. Feuchtgruber, The hydrogen ortho-to-para ratio in the stratospheres of the giant planets, Icarus 161, pp.127-143, 2003.

M. French, Equation of state and phase diagram of water at ultrahigh pressures as in planetary interiors, Phys. Rev. B, vol.79, p.54107, 2009.

A. J. Friedson and E. J. Gonzales, Inhibition of ordinary and diffusive convection in the water condensation zone of the ice giants and implications for their thermal evolution, Icarus, vol.297, pp.160-178, 2017.

J. Fuller, Saturn ring seismology: Evidence for stable stratification in the deep interior of Saturn, Icarus 242, pp.283-296, 2014.

B. J. Fulton, The California-Kepler Survey. III. A Gap in the Radius Distribution of Small Planets, AJ 154, vol.109, p.109, 2017.

E. Galanti, Saturn's Deep Atmospheric Flows Revealed by the Cassini Grand Finale Gravity Measurements, Geophys. Res. Lett, vol.46, pp.616-624, 2019.

P. Gaulme, Detection of Jovian seismic waves: a new probe of its interior structure, 2011.
URL : https://hal.archives-ouvertes.fr/hal-00632650

P. J. Gierasch and B. J. Conrath, Vertical temperature gradients on Uranus -Implications for layered convection, J. Geophys. Res, vol.92, pp.15019-15029, 1987.

P. J. Gierasch, Observation of moist convection in Jupiter's atmosphere, Nature 403, pp.628-630, 2000.

I. Gonçalves, First measurements of Jupiter's zonal winds with visible imaging spectroscopy, Icarus, vol.319, pp.795-811, 2019.

S. Guerlet, Global climate modeling of Saturn's atmosphere. Part I: Evaluation of the radiative transfer model, Icarus, vol.238, pp.110-124, 2014.

T. Guillot, THE INTERIORS OF GIANT PLAN-ETS: Models and Outstanding Questions, Annual Review of Earth and Planetary Sciences, vol.33, pp.493-530, 2005.

T. Guillot and D. Gautier, Giant Planets, 2014.
URL : https://hal.archives-ouvertes.fr/hal-00439598

T. Guillot and R. Hueso, The composition of Jupiter: sign of a (relatively) late formation in a chemically evolved protosolar disc, MNRAS, vol.367, pp.47-51, 2006.

T. Guillot, A suppression of differential rotation in Jupiter's deep interior, Nature, vol.555, pp.227-230, 2018.

T. Guillot, Condensation of Methane, Ammonia, and Water and the Inhibition of Convection in Giant Planets, Science 269, vol.5231, pp.1697-1699, 1995.

R. Helled, J. D. Anderson, and G. Schubert, Uranus and Neptune: Shape and rotation, Icarus 210, pp.446-454, 2010.

R. Helled, E. Galanti, and Y. Kaspi, Saturn's fast spin determined from its gravitational field and oblateness, Nature, vol.520, pp.202-204, 2015.

R. Helled and T. Guillot, Internal Structure of Giant and Icy Planets: Importance of Heavy Elements and Mixing, Handbook of Exoplanets, p.44, 2018.

W. B. Hubbard, M. Podolak, and D. J. Stevenson, The interior of Neptune, pp.109-138, 1995.

R. Hueso and A. Sánchez-lavega, A ThreeDimensional Model of Moist Convection for the Giant Planets: The Jupiter Case, Icarus 151, pp.257-274, 2001.

R. Hueso, A. Sánchez-lavega, and T. Guillot, A model for large-scale convective storms in Jupiter, Journal of Geophysical Research (Planets), vol.107, p.5075, 2002.

L. Iess, Measurement of Jupiter's asymmetric gravity field, Nature, vol.555, pp.220-222, 2018.

L. Iess, Measurement and implications of Saturn's gravity field and ring mass, Science, vol.364, p.2965, 2019.

M. Ikoma and Y. Hori, Situ Accretion of Hydrogen-rich Atmospheres on Short-period SuperEarths: Implications for the Kepler-11 Planets, vol.753, p.66, 2012.

A. P. Ingersoll, Atmospheric dynamics of the outer planets, Science, vol.248, pp.308-315, 1990.

A. P. Ingersoll and C. C. Porco, Solar heating and internal heat flow on Jupiter, Icarus 35, pp.27-43, 1978.

A. P. Ingersoll, Implications of the ammonia distribution on Jupiter from 1 to 100 bars as measured by the Juno microwave radiometer, Geophys. Res. Lett, vol.44, pp.7676-7685, 2017.

P. G. Irwin, Detection of hydrogen sulfide above the clouds in Uranus's atmosphere, Nature Astronomy, vol.2, pp.420-427, 2018.

P. G. Irwin, Latitudinal variation in the abundance of methane (CH 4 ) above the clouds in Neptune's atmosphere from VLT/MUSE Narrow Field Mode Observations, Icarus, vol.331, pp.69-82, 2019.

P. G. Irwin, Probable detection of hydrogen sulphide (H 2 S) in Neptune's atmosphere, Icarus, vol.321, pp.550-563, 2019.

A. Izidoro, Accretion of Uranus and Neptune from inward-migrating planetary embryos blocked by Jupiter and Saturn, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01162257

E. Karkoschka, Neptune's cloud and haze variations 1994-2008 from 500 HST-WFPC2 images, Icarus, vol.215, pp.759-773, 2011.

, Neptune's rotational period suggested by the extraordinary stability of two features, Icarus 215, pp.439-448, 2011.

Y. Kaspi, Atmospheric confinement of jet streams on Uranus and Neptune, Nature, vol.497, pp.344-347, 2013.

Y. Kaspi, Jupiter's atmospheric jet streams extend thousands of kilometres deep, Nature, vol.555, pp.223-226, 2018.

. Kaspi, G. R. Yohai, A. P. Flierl, and . Showman, The deep wind structure of the giant planets: Results from an anelastic general circulation model, Icarus 202, vol.2, pp.525-542, 2009.

K. Kurosaki and M. Ikoma, Acceleration of Cooling of Ice Giants by Condensation in Early Atmospheres, AJ 153, vol.260, p.260, 2017.

J. Leconte, Condensation-inhibited convection in hydrogen-rich atmospheres . Stability against double-diffusive processes and thermal profiles for Jupiter, A&A 598, vol.98, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01384469

C. Li and X. Chen, Simulating Nonhydrostatic Atmospheres on Planets (SNAP): Formulation, Validation, and Application to the Jovian Atmosphere, ApJS 240, vol.37, p.37, 2019.

C. Li, The distribution of ammonia on Jupiter from a preliminary inversion of Juno microwave radiometer data, Geophys. Res. Lett, vol.44, pp.5317-5325, 2017.

C. Li and A. P. Ingersoll, Moist convection in hydrogen atmospheres and the frequency of Saturn's giant storms, Nature Geoscience, vol.8, issue.5, pp.398-403, 2015.

G. F. Lindal, The atmosphere of Neptunean analysis of radio occultation data acquired with Voyager 2, AJ 103, pp.967-982, 1992.

J. Liu and T. Schneider, Mechanisms of Jet Formation on the Giant Planets, Journal of Atmospheric Sciences, vol.67, issue.11, pp.3652-3672, 2010.

J. I. Lunine and D. M. Hunten, Moist convection and the abundance of water in the troposphere of Jupiter, Icarus 69, pp.566-570, 1987.

C. Mankovich, Cassini Ring Seismology as a Probe of Saturn's Interior. I. Rigid Rotation, ApJ, vol.871, p.1, 2019.

S. Markham and D. Stevenson, Excitation mechanisms for Jovian seismic modes, Icarus, vol.306, pp.200-213, 2018.

S. T. Massie and D. M. Hunten, Conversion of para and ortho hydrogen in the Jovian planets, Icarus, vol.49, pp.213-226, 1982.

E. Miller-ricci, S. Seager, and D. Sasselov, The Atmospheric Signatures of Super-Earths: How to Distinguish Between Hydrogen-Rich and HydrogenPoor Atmospheres, ApJ, vol.690, p.808, 1902.

N. Monga and S. Desch, External Photoevaporation of the Solar Nebula: Jupiter's Noble Gas Enrichments, ApJ, vol.798, p.9, 2015.

O. Mousis, Determination of the Minimum Masses of Heavy Elements in the Envelopes of Jupiter and Saturn, ApJ 696, vol.2, pp.1348-1354, 2009.
URL : https://hal.archives-ouvertes.fr/hal-00388825

N. F. Ness, Magnetic fields at Uranus, Science, vol.233, pp.85-89, 1986.

N. F. Ness, Magnetic fields at Neptune, Science, vol.246, pp.1473-1478, 1989.

N. Nettelmann, New indication for a dichotomy in the interior structure of Uranus and Neptune from the application of modified shape and rotation data, Planet. Space Sci, vol.77, pp.143-151, 2013.

J. C. Pearl and B. J. Conrath, The albedo, effective temperature, and energy balance of Neptune, as determined from Voyager data, J. Geophys. Res, vol.96, p.18, 1991.

M. Podolak, W. B. Hubbard, and D. J. Stevenson, Model of Uranus' interior and magnetic field, pp.29-61, 1991.

P. L. Read, T. E. Dowling, and G. Schubert, Saturn's rotation period from its atmospheric planetarywave configuration, Nature, vol.460, pp.608-610, 2009.

A. Seiff, Thermal structure of Jupiter's atmosphere near the edge of a 5-µm hot spot in the north equatorial belt, J. Geophys. Res. 103, vol.10, pp.22857-22890, 1998.

A. P. Showman and A. P. Ingersoll, Interpretation of Galileo Probe Data and Implications for Jupiter's Dry Downdrafts, Icarus, vol.132, pp.205-220, 1998.

K. M. Soderlund, Turbulent models of ice giant internal dynamics: Dynamos, heat transfer, and zonal flows, Icarus, vol.224, pp.97-113, 2013.

F. Soubiran and B. Militzer, Miscibility Calculations for Water and Hydrogen in Giant Planets, ApJ, vol.806, p.228, 2015.

L. A. Sromovsky, P. M. Fry, and J. H. Kim, Methane on Uranus: The case for a compact CH 4 cloud layer at low latitudes and a severe CH 4 depletion at high-latitudes based on re-analysis of Voyager occultation measurements and STIS spectroscopy, Icarus, vol.215, pp.292-312, 2011.

L. A. Sromovsky, The methane distribution and polar brightening on Uranus based on HST/STIS, Keck/NIRC2, and IRTF/SpeX observations through, Icarus, vol.317, pp.266-306, 2015.

S. Stanley and J. Bloxham, Numerical dynamo models of Uranus' and Neptune's magnetic fields, Icarus, vol.184, pp.556-572, 2006.

D. J. Stevenson and E. E. Salpeter, The phase diagram and transport properties for hydrogenhelium fluid planets, ApJS, vol.35, pp.221-237, 1977.

C. R. Stoker, Moist convection -A mechanism for producing the vertical structure of the Jovian equatorial plumes, Icarus, vol.67, pp.106-125, 1986.

C. R. Stoker and O. B. Toon, Moist convection on Neptune, Geophys. Res. Lett, vol.16, pp.929-932, 1989.

K. Sugiyama, Numerical simulations of Jupiter's moist convection layer: Structure and dynamics in statistically steady states, Icarus 229, pp.71-91, 2014.

A. R. Vasavada and A. P. Showman, Jovian atmospheric dynamics: an update after Galileo and Cassini, In: Reports on Progress in Physics, vol.68, pp.1935-1996, 2005.

S. J. Weidenschilling and J. S. Lewis, Atmospheric and cloud structures of the Jovian planets, Icarus, vol.20, pp.465-476, 1973.

J. Wicht, T. Gastine, and L. D. Duarte, Dynamo Action in the Steeply Decaying Conductivity Region of Jupiter-Like Dynamo Models, Journal of Geophysical Research, pp.837-863, 2019.
URL : https://hal.archives-ouvertes.fr/hal-02125041

H. F. Wilson, M. L. Wong, and B. Militzer, Superionic to Superionic Phase Change in Water: Consequences for the Interiors of Uranus and Neptune, Physical Review Letters, vol.110, p.151102, 2013.

M. H. Wong, Updated Galileo probe mass spectrometer measurements of carbon, oxygen, nitrogen, and sulfur on Jupiter, Icarus, vol.171, pp.153-170, 2004.

Y. Yair, Z. Levin, and S. Tzivion, Microphysical processes and dynamics of a Jovian thundercloud, Icarus, vol.114, pp.278-299, 1995.