Bayesian Evolution Models for Jupiter With Helium Rain and Double-Diffusive Convection

Abstract: Hydrogen and helium demix when sufficiently cool, and this bears on the evolution of all giant planets at large separations at or below roughly a Jupiter mass. We model the thermal evolution of Jupiter, including its evolving helium distribution following results of ab initio simulations for helium immiscibility in metallic hydrogen. After 4 Gyr of homogeneous evolution, differentiation establishes a thin helium gradient below 1 Mbar that dynamically stabilizes the fluid to convection. The region undergoes ove… Show more

“…Although superadiabaticity resulting from some flavor of double-diffusive convection in metallic regions possessing helium gradients does modulate the cooling time for Jupiter and Saturn, it is not required in all cases. In particular, good solutions for Jupiter do require R ρ > 0, consistent with the expectation from earlier modeling efforts (e.g., Hubbard et al 1999;Fortney & Hubbard 2003;Fortney et al 2011;Nettelmann et al 2015;Mankovich et al 2016) that Jupiter required some mechanism (non-adiabatic interiors or otherwise) to speed its evolution rather than prolong it 2 . However, the new models find interiors that are closer to adiabatic (R ρ closer to zero) due to the major improvement in our understanding of the internal heat flow of Jupiter in light of results from Cassini (Li et al 2018).…”

“…The parameter estimation performed in this work provides statistically meaningful distributions of model parameters, estimating for instance that based on Jupiter's helium depletion, the true phase diagram is warmer than the most current ab initio phase diagram (Schöttler & Redmer 2018) by (539 ± 23) K (1σ uncertainty) at the ≈ 2 Mbar pressures that it predicts for the onset of helium immiscibility in metallic hydrogen. For comparison, Jupiter models built on a previous generation of phase diagram that assumed ideal hydrogen-helium mixing entropy predicted the necessary temperature offset to be between 200 and 300 K, in the opposite direction (Nettelmann et al 2015;Mankovich et al 2016). These findings imply a rather precise prediction for Saturn's atmospheric helium abundance summarized in Figure 14.…”

“…Assuming that hydrogen-helium immiscibility is the mechanism responsible for Jupiter's atmospheric helium depletion, the Galileo abundance measurement imposes a stringent constraint for discerning among viable, if still uncertain, phase diagrams. It is for this reason that, following Nettelmann et al (2015) and Mankovich et al (2016), we introduce a degree of freedom via an additive temperature offset ∆T phase modulating the overall temperature of the phase curves applied in this work, relative to SR18. This parameter allows us to explore a more general space of phase diagrams, with larger ∆T phase values leading to more pronounced differentiation, smaller values leading to less, and ∆T phase = 0 recovering the SR18 phase curves as published.…”

“…same simple, generic model as in Mankovich et al (2016). The temperature gradient is allowed to take on superadiabatic values in helium gradient regions, the value of the superadiabaticity assumed to be proportional to the magnitude of the helium gradient there following…”

“…As described in Section 2.3, the phase diagram temperature offset ∆T phase controls the temperatures of the hydrogen-helium phase curves and thus dictates the overall amount of helium differentiation. Finally the density ratio R ρ sets the superadiabaticity of the temperature profile in regions with continuous helium gradients, providing an additional degree of freedom in setting the rate of cooling from the planet's surface by limiting the flux emerging from the metallic interior (e.g., Nettelmann et al 2015;Mankovich et al 2016).…”

Evidence for a Dichotomy in the Interior Structures of Jupiter and Saturn from Helium Phase Separation

“…Although superadiabaticity resulting from some flavor of double-diffusive convection in metallic regions possessing helium gradients does modulate the cooling time for Jupiter and Saturn, it is not required in all cases. In particular, good solutions for Jupiter do require R ρ > 0, consistent with the expectation from earlier modeling efforts (e.g., Hubbard et al 1999;Fortney & Hubbard 2003;Fortney et al 2011;Nettelmann et al 2015;Mankovich et al 2016) that Jupiter required some mechanism (non-adiabatic interiors or otherwise) to speed its evolution rather than prolong it 2 . However, the new models find interiors that are closer to adiabatic (R ρ closer to zero) due to the major improvement in our understanding of the internal heat flow of Jupiter in light of results from Cassini (Li et al 2018).…”

“…The parameter estimation performed in this work provides statistically meaningful distributions of model parameters, estimating for instance that based on Jupiter's helium depletion, the true phase diagram is warmer than the most current ab initio phase diagram (Schöttler & Redmer 2018) by (539 ± 23) K (1σ uncertainty) at the ≈ 2 Mbar pressures that it predicts for the onset of helium immiscibility in metallic hydrogen. For comparison, Jupiter models built on a previous generation of phase diagram that assumed ideal hydrogen-helium mixing entropy predicted the necessary temperature offset to be between 200 and 300 K, in the opposite direction (Nettelmann et al 2015;Mankovich et al 2016). These findings imply a rather precise prediction for Saturn's atmospheric helium abundance summarized in Figure 14.…”

“…Assuming that hydrogen-helium immiscibility is the mechanism responsible for Jupiter's atmospheric helium depletion, the Galileo abundance measurement imposes a stringent constraint for discerning among viable, if still uncertain, phase diagrams. It is for this reason that, following Nettelmann et al (2015) and Mankovich et al (2016), we introduce a degree of freedom via an additive temperature offset ∆T phase modulating the overall temperature of the phase curves applied in this work, relative to SR18. This parameter allows us to explore a more general space of phase diagrams, with larger ∆T phase values leading to more pronounced differentiation, smaller values leading to less, and ∆T phase = 0 recovering the SR18 phase curves as published.…”

“…same simple, generic model as in Mankovich et al (2016). The temperature gradient is allowed to take on superadiabatic values in helium gradient regions, the value of the superadiabaticity assumed to be proportional to the magnitude of the helium gradient there following…”

“…As described in Section 2.3, the phase diagram temperature offset ∆T phase controls the temperatures of the hydrogen-helium phase curves and thus dictates the overall amount of helium differentiation. Finally the density ratio R ρ sets the superadiabaticity of the temperature profile in regions with continuous helium gradients, providing an additional degree of freedom in setting the rate of cooling from the planet's surface by limiting the flux emerging from the metallic interior (e.g., Nettelmann et al 2015;Mankovich et al 2016).…”

Evidence for a Dichotomy in the Interior Structures of Jupiter and Saturn from Helium Phase Separation

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

Internal Structure of Giant and Icy Planets: Importance of Heavy Elements and Mixing