Jupiter internal structure: the effect of different equations of state

Miguel, Yamila; Guillot, T.; Fayon, Lucile

doi:10.1051/0004-6361/201629732

Cited by 104 publications

(174 citation statements)

References 52 publications

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“…Finally, we also consider models using the SCvH EOS through the entire pressure range of the planet. Although the SCvH EOS does not fit the most recent data from high‐pressure shockwave experiments [ Hubbard and Militzer , ; Miguel et al , ], it is useful for comparison since it has been used to constrain Jupiter models in the past [e.g., Saumon and Guillot , ].…”

Section: Methodsmentioning

confidence: 99%

Comparing Jupiter interior structure models to Juno gravity measurements and the role of a dilute core

Wahl

Hubbard

Militzer

et al. 2017

Geophysical Research Letters

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348

361

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The Juno spacecraft has measured Jupiter's low‐order, even gravitational moments, J2–J8, to an unprecedented precision, providing important constraints on the density profile and core mass of the planet. Here we report on a selection of interior models based on ab initio computer simulations of hydrogen‐helium mixtures. We demonstrate that a dilute core, expanded to a significant fraction of the planet's radius, is helpful in reconciling the calculated Jn with Juno's observations. Although model predictions are strongly affected by the chosen equation of state, the prediction of an enrichment of Z in the deep, metallic envelope over that in the shallow, molecular envelope holds. We estimate Jupiter's core to contain a 7–25 Earth mass of heavy elements. We discuss the current difficulties in reconciling measured Jn with the equations of state and with theory for formation and evolution of the planet.

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Section: Methodsmentioning

confidence: 99%

Comparing Jupiter interior structure models to Juno gravity measurements and the role of a dilute core

Wahl

Hubbard

Militzer

et al. 2017

Geophysical Research Letters

Self Cite

348

361

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“…These values should be taken with care, as (1) Jupiter's internal structure (and, thus, M Z ) depends on the equations of state and the accuracy of the observational constrains (e.g. gravitational moments) (see, e.g., Saumon & Guillot 2004;Miguel et al 2016, and references therein) and (2) the distribution of M Z in Jupiter might be inhomogeneous. Several additional steps could be taken if one wanted to perform a more detailed estimation of the C/O ratios of the studied planets.…”

Section: Hat-p-20bmentioning

confidence: 99%

Metal Enrichment Leads to Low Atmospheric C/O Ratios in Transiting Giant Exoplanets

Espinoza

Fortney

Miguel

et al. 2017

ApJL

120

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We predict the carbon-to-oxygen (C/O) ratios in the hydrogen-helium envelope and atmospheres of a sample of nearly 50 relatively cool (T eq < 1000 K) transiting gas giant planets. The method involves planetary envelope metallicity estimates that use the structure models of Thorngren et al. (2016) and the disk and planetary accretion model ofÖberg et al. (2011). We find that nearly all of these planets are strongly metal-enriched which, coupled with the fact that solid material is the main deliverer of metals in the protoplanetary disk, implies that the substellar C/O ratios of their accreted solid material dominate compared to the enhanced C/O ratio of their accreted gaseous component. We predict that these planets will have atmospheres that are typically reduced in their C/O compared to parent star values independent of the assessed formation locations, with C/O < 1 a nearly universal outcome within the framework of the model. We expect water vapor absorption features to be ubiquitous in the atmospheres of these planets, and by extension, other gas giants.

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“…These points are used to constrain the phase boundaries (dashed lines) where a clear first-order transition is absent or difficult to identify. Also shown is Jupiter's adiabat (grey line) as calculated by Miguel et al 6 . We compare the LLT for classical nuclei pure H with recent QMC simulations of Pierleoni et.…”

mentioning

confidence: 99%

“…We show that H-REOS.3 is in perfect agreement with our DFT calculations, whereas the MH-SCvH-H EOS (extrapolating the data in the limiting case of pure H 6 ) is closer to our QMC one. The disagreement between the two EOSs could be caused by the extrapolation 6 , and it seems that the disagreement between these two groups is linked to the calculated entropies 6,36 . Either way, it is clear that QMC implies a denser EOS for H at Jupiter's conditions, which translates to an envelope that is poor in heavy elements.…”

mentioning

confidence: 99%

Phase Diagram of Hydrogen and a Hydrogen-Helium Mixture at Planetary Conditions by Quantum Monte Carlo Simulations

2018

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Understanding planetary interiors is directly linked to our ability of simulating exotic quantum mechanical systems such as hydrogen (H) and hydrogen-helium (H-He) mixtures at high pressures and temperatures 1 . Equations of State (EOSs) tables based on Density Functional Theory (DFT), are commonly used by planetary scientists, although this method allows only for a qualitative description of the phase diagram 2 , due to an incomplete treatment of electronic interactions 3 . Here we report Quantum Monte Carlo (QMC) molecular dynamics simulations of pure H and H-He mixture. We calculate the first QMC EOS at 6000 K for an H-He mixture of a proto-solar composition, and show the crucial influence of He on the H metallization pressure. Our results can be used to calibrate other EOS calculations and are very timely given the accurate determination of Jupiter's gravitational field from the NASA Juno mission and the effort to determine its structure 4 .Since a few decades the link between the uncertainty of the H EOS and the internal structure of Jupiter (and other gaseous planets) has been investigated and many efforts to model Jupiter's interior have been carried 1,5-7 . The computation of an EOS from first principles requires to solve a many-body quantum mechanical problem, a task which is beyond the currently available theoretical and computational capabilities. In practice, we must resort to several approximations. The first is to decouple the ionic and electronic problems and consider the ions as classical or quantum particles, determining their motion by following the Born-Oppenheimer potential energy surface. The second approximation concerns the description of the electronic interaction and the exchange one, due to the Pauli exclusion principle.The standard approach to EOS calculations relies on Density Functional Theory (DFT), which targets the tridimensional electronic density rather than the (N e electrons) many-body wave-function. Its success and simplicity have lead to a widespread application in materials science and to the development of several software packages which allow fast and reproducible calculations 8 . Although DFT is formally exact, the explicit functional form to describe the exchange and correlation (XC) effects between electrons remains approximated 3 . Indeed, a systematic and efficient route to improve XC functional is still lacking. Therefore, in practical solid state calculations, benchmarks against experimental data, are often required to validate the XC functional used to describe the system in a satisfactory manner.Dense hydrogen systems, both in the low temperature solid and in the liquid phase remain a challenge to DFT simulations due to the interplay of strong correlation and non-covalent interactions between the atoms. DFT calculations with different functionals produce different results with the expected metallization pressure varying over a range of 100-200 GPa (Fig. 1) 12,13 . Since experimental data are limited, it is not possible to identify a posteriori the best functional...

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Jupiter internal structure: the effect of different equations of state

Cited by 104 publications

References 52 publications

Comparing Jupiter interior structure models to Juno gravity measurements and the role of a dilute core

Comparing Jupiter interior structure models to Juno gravity measurements and the role of a dilute core

Metal Enrichment Leads to Low Atmospheric C/O Ratios in Transiting Giant Exoplanets

Phase Diagram of Hydrogen and a Hydrogen-Helium Mixture at Planetary Conditions by Quantum Monte Carlo Simulations

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