A Comparison of the Composition of Planets in Single-planet and Multiplanet Systems Orbiting M dwarfs

We investigate and compare the composition of M-dwarf planets in systems with only one known planet (“singles”) to those residing in multiplanet systems (“multis”) and the fundamental properties of their host stars. We restrict our analysis to planets with directly measured masses and radii, which c...

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Bibliographic Details
Published in:The Astronomical journal 2023-10, Vol.166 (4), p.137
Main Authors: Rodríguez Martínez, Romy, Martin, David V., Gaudi, B. Scott, Schulze, Joseph G., Asnodkar, Anusha Pai, Boley, Kiersten M., Ballard, Sarah
Format: Article
Language:English
Subjects:
Astronomy
Bulk density
Dwarf planets
Earth models
Exoplanet formation
Exoplanet systems
Metallicity
Planetary composition
Planetary rotation
Planets
Red dwarf stars
Stars
Water masses
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Summary:We investigate and compare the composition of M-dwarf planets in systems with only one known planet (“singles”) to those residing in multiplanet systems (“multis”) and the fundamental properties of their host stars. We restrict our analysis to planets with directly measured masses and radii, which comprise a total of 70 planets: 30 singles and 40 multis in 19 systems. We compare the bulk densities for the full sample, which includes planets ranging in size from 0.52 R ⊕ to 12.8 R ⊕ , and find that single planets have significantly lower densities on average than multis, which we cannot attribute to selection biases. We compare the bulk densities normalized by an Earth model for planets with R p < 6 R ⊕ and find that multis are also denser with 99% confidence. We calculate and compare the core/water mass fractions (CMF/WMF) of low-mass planets ( M p < 10 M ⊕ ) and find that the likely rocky multis (with R p < 1.6 R ⊕ ) have lower CMFs than singles. We also compare the [Fe/H] metallicity and rotation period of all single-planet versus multiplanet host stars with such measurements in the literature and find that multiplanet hosts are significantly more metal-poor than those hosting a single planet. Moreover, we find that the host star metallicity decreases with increasing planet multiplicity. In contrast, we find only a modest difference in the rotation period. The significant differences in planetary composition and metallicity of the host stars point to different physical processes governing the formation of single-planet and multiplanet systems in M dwarfs.
ISSN:0004-6256
1538-3881
DOI:10.3847/1538-3881/aced9a