The Pressure and Temperature Limits of Likely Rocky Exoplanets

Unterborn, Cayman T.; Panero, W. R.

doi:10.1029/2018je005844

Cited by 69 publications

(90 citation statements)

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“…Density and pressure profiles within the interior of super‐Earths with 1 to 10 Earth masses ( M E ) and CMFs of 0.2 (Mars like), 0.32 (Earth like), and 0.68 (Mercury like) are shown in Figure 2. Statistics of observed exoplanet populations suggest that exoplanets with radii larger than 1.5 Earth radii have relatively small bulk density indicating the presence of a substantial gaseous envelope (Rogers, 2015; Unterborn & Panero, 2019; Weiss & Marcy, 2014). Even though super‐Earths larger than 1.5 R E may be rare, we argue they are still worth investigating.…”

Section: Resultsmentioning

confidence: 99%

Super‐Earth Internal Structures and Initial Thermal States

2020

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The presence of a planetary magnetic field is an important ingredient for habitability. The coexistence of a solid and a liquid core can facilitate the maintenance of a compositionally driven dynamo; however, the likelihood of such a configuration in super-Earths is unknown. Recently, shock experiments and ab initio calculations have constrained the stability, equations of state, and melting properties of ultrahigh pressure core and mantle phases. Here, we investigate the internal structure of super-Earth exoplanets with a range of total masses and core mass fractions ranging from that of Mars (0.2) to Mercury (0.68), including an Earth-like bulk composition. We examine the effect of the initial core-mantle boundary temperature (T CMB ) on their internal structure and identify regimes with coexisting solid and liquid cores, and deep mantle melting. We find that the range of T CMB for which an inner core is growing increases with the total planet mass and even more with the core mass fraction. Therefore, our results suggest that super-Earths should have a crystallizing core over a large temperature range. We also find that the presence of a growing inner core is likely to be accompanied by a partially liquid lower mantle, which will likely influence planetary thermal evolution. We estimate the initial CMB temperature after super-Earth accretion by assuming an accretional heat retention efficiency similar to Earth. We find that massive super-Earths are expected to have an initial internal temperature consistent with a partially liquid core, allowing for the possibility of thermal and compositional dynamo action. Plain Language SummaryThe presence of a magnetic field in a planetary body is an important criterion for habitability, since it may reduce atmospheric loss and shield planetary surfaces from high-energy charged particles. In terrestrial planets, when an inner iron-rich core crystallizes, it releases light elements in the residual liquid outer core, which can facilitate liquid iron alloy convection and contribute to the maintenance of a magnetic field. In this study, we investigate the optimal conditions for the presence of a crystallizing core in super-Earths (i.e., large rocky exoplanets), by modeling their internal structure and using recent data on the melting properties of materials at ultrahigh pressure. We find that cores of super-Earths of large sizes have a greater likelihood to be partially molten, which may aid in maintaining a magnetic field. In addition, the lowermost mantle of massive super-Earths are likely to experience prolonged partial melting. Increasing the size of their core relative to their mantle increases even more the probability of a growing inner core. In addition, we calculate the initial heat retained during planetary formation, which confirms that large super-Earths are likely to have an initial crystallizing core.

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Section: Resultsmentioning

confidence: 99%

Super‐Earth Internal Structures and Initial Thermal States

2020

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“…Given the mass and radius for both planets, there are significant constraints for inferences to their interior structures in the context of composition. Namely, the stellar elemental abundances (see Section 2) would need to be measured to a higher precision, 0.02-0.04dex (Hinkel & Unterborn 2018), necessary to meaningfully constrain the mineralogy (Unterborn & Panero 2019). In addition, fundamental to all of the mass-radius models are critical assumptions regarding the composition of rocky exoplanets and the underlying mineral physics.…”

Section: Exoplanet Demographicsmentioning

confidence: 99%

“…In addition, fundamental to all of the mass-radius models are critical assumptions regarding the composition of rocky exoplanets and the underlying mineral physics. These assumptions typically cause over-or underpredictions in empirical models (e.g., Zeng et al 2016) when characterizing ultrahigh pressures present in the cores of super-Earths and mini-Neptunes (Unterborn & Panero 2019).…”

Section: Exoplanet Demographicsmentioning

confidence: 99%

Transits of Known Planets Orbiting a Naked-eye Star

Kane

Yalçınkaya

Osborn

et al. 2020

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Some of the most scientifically valuable transiting planets are those that were already known from radial velocity (RV) surveys. This is primarily because their orbits are well characterized and they preferentially orbit bright stars that are the targets of RV surveys. The Transiting Exoplanet Survey Satellite (TESS) provides an opportunity to survey most of the known exoplanet systems in a systematic fashion to detect possible transits of their planets. HD136352 (Nu 2 Lupi) is a naked-eye (V=5.78) G-type main-sequence star that was discovered to host three planets with orbital periods of 11.6, 27.6, and 108.1 days via RV monitoring with the High Accuracy Radial velocity Planet Searcher (HARPS) spectrograph. We present the detection and characterization of transits for the two inner planets of the HD136352 system, revealing radii of-+ 0.41 g cm −3 for planets b and c, respectively, thus placing them on either side of the radius valley. The combination of the multitransiting planet system, the bright host star, and the diversity of

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“…Planets identified with both techniques are characterized by their mass and radius, which, combined, provide a first indication of the bulk composition through comparison with theoretical mass-radius curves (e.g., Valencia et al 2006;Sotin et al 2007;Zeng & Sasselov 2013). A common approach to the interior characterization of exoplanets is the use of numerical models to compute interior structures which comply with the measured mass and radius of the planet (e.g., Sotin et al 2007;Valencia et al 2007;Fortney et al 2007;Wagner et al 2011;Zeng & Sasselov 2013;Unterborn & Panero 2019). As this is an inverse problem, it requires the calculation of a large number of interior models to obtain an overview over possible interior structures (Rogers & Seager 2010a;Dorn et al 2017;Brugger et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Machine-learning Inference of the Interior Structure of Low-mass Exoplanets

Baumeister

Padovan

Tosi

et al. 2020

ApJ

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We explore the application of machine learning based on mixture density neural networks (MDNs) to the interior characterization of low-mass exoplanets up to 25 Earth masses constrained by mass, radius, and fluid Love number k 2 . We create a dataset of 900 000 synthetic planets, consisting of an iron-rich core, a silicate mantle, a high-pressure ice shell, and a gaseous H/He envelope, to train a MDN using planetary mass and radius as inputs to the network. For this layered structure, we show that the MDN is able to infer the distribution of possible thicknesses of each planetary layer from mass and radius of the planet. This approach obviates the time-consuming task of calculating such distributions with a dedicated set of forward models for each individual planet. While gas-rich planets may be characterized by compositional gradients rather than distinct layers, the method presented here can be easily extended to any interior structure model. The fluid Love number k 2 bears constraints on the mass distribution in the planets' interior and will be measured for an increasing number of exoplanets in the future. Adding k 2 as an input to the MDN significantly decreases the degeneracy of the possible interior structures. In an open repository we provide the trained MDN to be used through a Python Notebook.

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The Pressure and Temperature Limits of Likely Rocky Exoplanets

Cited by 69 publications

References 50 publications

Super‐Earth Internal Structures and Initial Thermal States

Super‐Earth Internal Structures and Initial Thermal States

Transits of Known Planets Orbiting a Naked-eye Star

Machine-learning Inference of the Interior Structure of Low-mass Exoplanets

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