The Mass-Metallicity Relation for Giant Planets (1511.07854v2)

Abstract: Exoplanet discoveries of recent years have provided a great deal of new data for studying the bulk compositions of giant planets. Here we identify 47 transiting giant planets ($20 M_\oplus < M < 20 M_{\mathrm{J}}$) whose stellar insolation is low enough ($F_* < 2\times10^8\; \text{erg}\; \text{s}^{-1}\; \text{cm}^{-2}$, or roughly $T_\text{eff} < 1000$) that they are not affected by the hot Jupiter radius inflation mechanism(s). We compute a set of new thermal and structural evolution models and use these models in comparison with properties of the 47 transiting planets (mass, radius, age) to determine their heavy element masses. A clear correlation emerges between the planetary heavy element mass $M_z$ and the total planet mass, approximately of the form $M_z \propto \sqrt{M}$. This finding is consistent with the core accretion model of planet formation. We also study how stellar metallicity [Fe/H] affects planetary metal-enrichment and find a weaker correlation than has been previously reported from studies with smaller sample sizes. We confirm a strong relationship between the planetary metal-enrichment relative to the parent star $Z_{\rm planet}/Z_{\rm star}$ and the planetary mass, but see no relation in $Z_{\rm planet}/Z_{\rm star}$ with planet orbital properties or stellar mass. The large heavy element masses of many planets ($>50$ $M_{\oplus}$) suggest significant amounts of heavy elements in H/He envelopes, rather than cores, such that metal-enriched giant planet atmospheres should be the rule. We also discuss a model of core-accretion planet formation in a one-dimensional disk and show that it agrees well with our derived relation between mass and $Z_{\rm planet}/Z_{\rm star}$.

Overview of The Mass-Metallicity Relation for Giant Planets

This paper presents an analysis of the mass-metallicity relation for transiting giant exoplanets, focusing on planets with temperatures conducive to uninflated radii. The authors identify a correlation between the heavy element mass and the total mass of the planet, ascertaining a relationship consistent with the core accretion model of planetary formation. Through the paper of 47 giant planets, the research explores correlations with stellar metallicity, planetary mass, and planet-stellar metallicity ratios in order to derive insights into planetary compositions and formation.

Methodology and Modeling

The analysis employs thermal and structural evolution models to estimate the heavy element content of giant planets. The methodology involves selecting relatively cool planets that adhere to specific flux thresholds to avoid the complexities introduced by hot Jupiter inflation mechanisms. By circumventing inflated hot Jupiters, the models more accurately determine planetary characteristics, including mass and radius, without complicating factors.

The heavy element distributions are modeled with a core-envelope structure to assess compositional variations of heavy elements. The paper discusses considerations regarding homogeneity and the placement of heavy elements within the planetary interiors and uses Monte Carlo methods to derive uncertainties in parameter estimates. Selection criteria include well-determined planet properties to ensure precise conclusions regarding heavy-element mass fractions.

Outcomes and Findings

The research highlights several notable points:

• Mass-Metallicity Relation: A distinct correlation was established, where heavier planets tend to possess greater quantities of metals (heavy elements). The approximate relationship $M_{z} \propto M_{p}^{0.61}$ suggests increasing heavy element mass with planetary mass but a decreasing bulk metallicity fraction.
• Stellar Metallicity: Although previous work found a correlation between stellar metallicity [Fe/H] and planetary metal enrichment, the expanded dataset renders this correlation less distinct, leaning towards a probabilistic rather than deterministic relationship.
• Metal Enrichment: Planets show metal enrichment relative to their parent stars, suggesting significant amounts of heavy elements in planetary envelopes. The observed metal ratios $Z_{\text{planet}}/Z_{\star} \propto M_{p}^{-0.45}$, indicating that more massive planets are relatively less enriched.

Implications and Future Considerations

The findings imply that core accretion is a principal mechanism behind planetary formation, as evidenced by the heavy-element mass correlation with planetary mass. Furthermore, the enrichment of planetary atmospheres suggests widespread distribution of metals throughout giant planets, warranting further investigation via spectroscopic techniques, such as those planned with the James Webb Space Telescope.

The paper lays groundwork for future studies that might investigate stellar metal abundances beyond iron, considering elements that could potentially correlate more strongly with planetary compositions (e.g., oxygen for its role in compound formations). Moreover, expanding the scope of transiting exoplanet samples to include more cool gas giants will further elucidate these observed relationships and inform theoretical models.

Overall, this paper delineates important patterns in exoplanetary characteristics and formation theories, contributing significantly to the understanding of giant planet compositions.