Predicting Exoplanet Masses and Radii: A Nonparametric Approach

Ning, Bo; Wolfgang, Angie; Ghosh, Sujit K.

doi:10.3847/1538-4357/aaeb31

Cited by 71 publications

(113 citation statements)

References 49 publications

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“…This low value for the low mass break is below most planets in the sample, perhaps indicating weak support for including this break based on the CKS sample. This is supported by the nonparametric mass-radius relation fit by Ning et al (2018), which found no evidence for a low mass break in the mass-radius relation with the current mass-radius sample. The scatter parameters σ 0 , σ 1 , σ 2 that we retrieve are higher across the board (0.07 +0.02 −0.01 vs 0.04 +0.01 −0.01 , 0.27 +0.03 −0.03 vs 0.15 +0.02 −0.01 , and 0.11 +0.03 −0.02 vs 0.07 +0.01 −0.01 , respectively).…”

Section: Model Fitssupporting

confidence: 59%

A Joint Mass–Radius–Period Distribution of Exoplanets

Neil

Rogers

2020

ApJ

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The radius-period distribution of exoplanets has been characterized by the Kepler survey, and the empirical mass-radius relation by the subset of Kepler planets with mass measurements. We combine the two in order to constrain the joint mass-radius-period distribution of Kepler transiting planets. We employ hierarchical Bayesian modeling and mixture models to formulate four models with varying complexity and fit these models to the data. We find that the most complex models that treat planets with significant gaseous envelopes, evaporated core planets, and intrinsically rocky planets as three separate populations are preferred by the data and provide the best fit to the observed distribution of Kepler planets. We use these models to calculate occurrence rates of planets in different regimes and to predict masses of Kepler planets, revealing the model dependent nature of both. When using models with envelope mass loss to calculate η ⊕ , we find nearly an order of magnitude drop, indicating that many Earth-like planets discovered with Kepler may be evaporated cores which do not extrapolate out to higher orbital periods. This work provides a framework for higher-dimensional studies of planet occurrence and for using mixture models to incorporate different theoretical populations of planets.

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Section: Model Fitssupporting

confidence: 59%

A Joint Mass–Radius–Period Distribution of Exoplanets

Neil

Rogers

2020

ApJ

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“…Assuming that the V1298 Tau planets will follow the mature exoplanet mass-radius relation of Chen & Kipping (2017) in the future, we calculated the expected final radii to estimate that the planets might contract by 40-90% (68% confidence interval) over the subsequent evolution of the system. These results are not changed significantly when adopting the nonparametric mass-radius relation of Ning et al (2018).…”

Section: Estimating Planet Massesmentioning

confidence: 85%

Four Newborn Planets Transiting the Young Solar Analog V1298 Tau

David

Petigura

Luger

et al. 2019

ApJL

153

158

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Exoplanets orbiting pre-main sequence stars are laboratories for studying planet evolution processes, including atmospheric loss, orbital migration, and radiative cooling. V1298 Tau, a young solar analog with an age of 23 ± 4 Myr, is one such laboratory. The star is already known to host a Jupiter-sized planet on a 24 day orbit. Here, we report the discovery of three additional planets -all between the size of Neptune and Saturn -based on our analysis of K2 Campaign 4 photometry. Planets c and d have sizes of 5.6 and 6.4 R ⊕ , respectively and with orbital periods of 8.25 and 12.40 days reside 0.25% outside of the nominal 3:2 mean-motion resonance. Planet e is 8.7 R ⊕ in size but only transited once in the K2 time series and thus has a period longer than 36 days, but likely shorter than 223 days. The V1298 Tau system may be a precursor to the compact multiplanet systems found to be common by the Kepler mission. However, the large planet sizes stand in sharp contrast to the vast majority of Kepler multis which have planets smaller than 3 R ⊕ . Simple dynamical arguments suggest total masses of <28 M ⊕ and <120 M ⊕ for the c-d and d-b planet pairs, respectively. The implied low masses suggest that the planets may still be radiatively cooling and contracting, and perhaps losing atmosphere. The V1298 Tau system offers rich prospects for further follow-up including atmospheric characterization by transmission or eclipse spectroscopy, dynamical characterization 2 David et al.through transit-timing variations, and measurements of planet masses and obliquities by radial velocities.

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“…The planet transit time was uniform over the timespan of the observations, and inclination was uniform from 0 − 90 • . The planet mass was log-normally distributed, M p ∼ 10 2.5±0.5 M ⊕ , based on the expectation for Jupiter-radius objects from Ning et al (2018). For the moon model, we allowed the transit time to vary uniformly over the entire visit.…”

Section: Astrophysics Modelmentioning

confidence: 99%

No Evidence for Lunar Transit in New Analysis of Hubble Space Telescope Observations of the Kepler-1625 System

Kreidberg

Luger

Bedell

2019

ApJL

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Observations of the Kepler-1625 system with the Kepler and Hubble Space Telescopes have suggested the presence of a candidate exomoon, Kepler-1625b I, a Neptune-radius satellite orbiting a long-period Jovian planet. Here we present a new analysis of the Hubble observations, using an independent data reduction pipeline. We find that the transit light curve is well fit with a planet-only model, with a best-fit χ 2 ν equal to 1.01. The addition of a moon does not significantly improve the fit quality. We compare our results directly with the original light curve from , and find that we obtain a better fit to the data using a model with fewer free parameters (no moon). We discuss possible sources for the discrepancy in our results, and conclude that the lunar transit signal found by was likely an artifact of the data reduction. This finding highlights the need to develop independent pipelines to confirm results that push the limits of measurement precision.

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Predicting Exoplanet Masses and Radii: A Nonparametric Approach

Cited by 71 publications

References 49 publications

A Joint Mass–Radius–Period Distribution of Exoplanets

A Joint Mass–Radius–Period Distribution of Exoplanets

Four Newborn Planets Transiting the Young Solar Analog V1298 Tau

No Evidence for Lunar Transit in New Analysis of Hubble Space Telescope Observations of the Kepler-1625 System

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