Tracing bulk elemental ratios in exoplanetary atmospheres with TiO chemistry

Ramírez, Vanesa; Cridland, Alex J.; Mollière, P.

doi:10.1051/0004-6361/202038186

Cited by 4 publications

(4 citation statements)

References 63 publications

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“…For nitrogen we use N 2 and NH 3 , where most of the nitrogen should be in the form of N 2 (e.g., Bosman et al 2019). Even though Ti, Al, K, Na, and V are not very abundant and thus do not contribute significantly to the planetary accretion rates, we include these elements in our model because they can be observed in the atmospheres of hot Jupiters and could also play a crucial role for the chemical evolution inside the atmospheres (Ramírez et al 2020).…”

Section: Compositionsmentioning

confidence: 99%

How drifting and evaporating pebbles shape giant planets

Bitsch

2021

A&A

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Recent observations of extrasolar gas giants suggest super-stellar C/O ratios in planetary atmospheres, while interior models of observed extrasolar giant planets additionally suggest high heavy element contents. Furthermore, recent observations of protoplanetary disks revealed super-solar C/H ratios, which are explained by inward drifting and evaporating pebbles enhancing the volatile content of the disk. We investigate in this work how the inward drift and evaporation of volatile-rich pebbles influences the atmospheric C/O ratio and heavy element content of giant planets growing by pebble and gas accretion. To achieve this goal, we perform semi-analytical 1D models of protoplanetary disks, including the treatment of viscous evolution and heating, pebble drift, and simple chemistry to simulate the growth of planets from planetary embryos to Jupiter-mass objects by the accretion of pebbles and gas while they migrate through the disk. Our simulations show that the composition of the planetary gas atmosphere is dominated by the accretion of vapor that originates from inward drifting evaporating pebbles at evaporation fronts. This process allows the giant planets to harbor large heavy element contents, in contrast to models that do not take pebble evaporation into account. In addition, our model reveals that giant planets originating farther away from the central star have a higher C/O ratio on average due to the evaporation of methane-rich pebbles in the outer disk. These planets can then also harbor super-solar C/O ratios, in line with exoplanet observations. However, planets formed in the outer disk harbor a smaller heavy element content due to a smaller vapor enrichment of the outer disk compared to the inner disk, where the very abundant water ice also evaporates. Our model predicts that giant planets with low or large atmospheric C/O should harbor a large or low total heavy element content. We further conclude that the inclusion of pebble evaporation at evaporation lines is a key ingredient for determining the heavy element content and composition of giant planets.

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Section: Compositionsmentioning

confidence: 99%

How drifting and evaporating pebbles shape giant planets

Bitsch

2021

A&A

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“…It is not included in the UMIST Database for Astrochemistry (UDfA) (McElroy et al 2013) or in Kinetic Database for Astrochemistry (KIDA) (Wakelam et al 2012). We incorporate available reactions (Tsai et al 2021;Churchwell et al 1980;Ramírez et al 2020), but these are small in number. We adopted Si-based chemistry as a proxy for the missing Ti chemistry.…”

Section: Updated Ti-chemistry In Cloudymentioning

confidence: 99%

“…For example, in the reference column Si5209 refers a copied reaction from Si reaction of UDfA2012 with the reaction number 5209. Ref 1, 2, and 3 refer to Churchwell et al (1980), Ramírez et al (2020), andTsai et al (2021), respectively. The rate coefficient for the reaction, Ti + + H − → Ti + H, is taken from Dalgarno & McCray (1973).…”

Section: Appendixmentioning

confidence: 99%

Recent Updates of Gas-phase Chemical Reactions and Molecular Lines of SiS in CLOUDY

2023

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“…Hobbs et al (2019) used a photochemical kinetic model to show that the abundances of C-and O-bearing species, such as H 2 O and CO, are insensitive to N/H ratio in hot Jupiters like HD 209458b. Ramírez et al (2020) also investigated the impact of N/H ratio on TiO abundances in ultrahot Jupiters and found that the TiO abundance is nearly independent of N/H. Since the abundances of C-and O-bearing species are insensitive to bulk nitrogen abundance in substellar atmospheres, it appears that the only route to diagnose the bulk nitrogen abundance of a giant planet is from NH 3 and/or HCN.…”

Section: Introductionmentioning

confidence: 99%

Nitrogen as a Tracer of Giant Planet Formation. I. A Universal Deep Adiabatic Profile and Semianalytical Predictions of Disequilibrium Ammonia Abundances in Warm Exoplanetary Atmospheres

Ohno

Fortney

2023

ApJ

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A major motivation of spectroscopic observations of giant exoplanets is to unveil planet formation processes from atmospheric compositions. Several recent studies suggested that atmospheric nitrogen, like carbon and oxygen, can provide important constraints on planetary formation environments. Since nitrogen chemistry can be far from thermochemical equilibrium in warm atmospheres, we extensively investigate under what conditions, and with what assumptions, the observable NH3 abundances can diagnose an atmosphere’s bulk nitrogen abundance. In the first paper of this series, we investigate atmospheric T–P profiles across equilibrium temperature, surface gravity, intrinsic temperature, atmospheric metallicity, and C/O ratio using a 1D radiative–convective equilibrium model. Models with the same intrinsic temperature and surface gravity coincide with a shared “universal” adiabat in the deep atmosphere, across a wide equilibrium temperature range (250–1200 K), which is not seen in hotter or cooler models. We explain this behavior in terms of the classic “radiative zero solution” and then establish a semianalytical T–P profile of the deep atmospheres of warm exoplanets. This profile is then used to predict vertically quenched NH3 abundances. At solar metallicity, our results show that the quenched NH3 abundance only coincides with the bulk nitrogen abundance (within 10%) at low intrinsic temperature, corresponding to a planet with a sub-Jupiter mass (≲1 M J) and old age (≳1 Gyr). If a planet has a high-metallicity (≳10× solar) atmosphere, the quenched NH3 abundance significantly underestimates the bulk nitrogen abundance at almost all planetary masses and ages. We suggest modeling and observational strategies to improve the assessment of bulk nitrogen from NH3.

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Tracing bulk elemental ratios in exoplanetary atmospheres with TiO chemistry

Cited by 4 publications

References 63 publications

How drifting and evaporating pebbles shape giant planets

How drifting and evaporating pebbles shape giant planets

Recent Updates of Gas-phase Chemical Reactions and Molecular Lines of SiS in CLOUDY

Nitrogen as a Tracer of Giant Planet Formation. I. A Universal Deep Adiabatic Profile and Semianalytical Predictions of Disequilibrium Ammonia Abundances in Warm Exoplanetary Atmospheres

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