Setting the volatile composition of (exo)planet-building material

Eistrup, Christian; Walsh, Catherine; Dishoeck, E. F. van

doi:10.1051/0004-6361/201628509

Cited by 160 publications

(349 citation statements)

References 80 publications

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“…A similar distribution of gas-phase H 2 O in the midplane of a Herbig Ae disk is reported in Figure 1 of Woitke et al (2009b). Here we also note that Eistrup et al (2016) calculated the chemical evolution of a disk midplane under both molecular and atomic initial conditions as initial chemical abundances. They showed that in the latter atomic conditions, the abundance of H 2 O gas and ice around the H 2 O snowline (∼ 10 −6 ) is smaller than that for molecular initial abundances (∼ 10 −4 ).…”

Section: The Distributions Of H 2 O Gas and Icesupporting

confidence: 81%

Candidate Water Vapor Lines to Locate the H₂O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

Notsu

Nomura

Ishimoto

et al. 2017

ApJ

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Observationally measuring the location of the H 2 O snowline is crucial for understanding the planetesimal and planet formation processes, and the origin of water on Earth. In disks around Herbig Ae stars (T * ∼10,000K, M * 2.5M ), the position of the H 2 O snowline is further from the central star compared with that around cooler, and less massive T Tauri stars. Thus, the H 2 O emission line fluxes from the region within the H 2 O snowline are expected to be stronger. In this paper, we calculate the chemical composition of a Herbig Ae disk using chemical kinetics. Next, we calculate the H 2 O emission line profiles, and investigate the properties of candidate water lines across a wide range of wavelengths (from mid-infrared to sub-millimeter) that can locate the position of the H 2 O snowline. Those line identified have small Einstein A coefficients (∼ 10 −6 − 10 −3 s −1 ) and relatively high upper state energies (∼ 1000K). The total fluxes tend to increase with decreasing wavelengths. We investigate the possibility of future observations (e.g., ALMA, SPICA/SMI-HRS) to locate the position of the H 2 O snowline. Since the fluxes of those identified lines from Herbig Ae disks are stronger than those from T Tauri disks, the possibility of a successful detection is expected to increase for a Herbig Ae disk.

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Section: The Distributions Of H 2 O Gas and Icesupporting

confidence: 81%

Candidate Water Vapor Lines to Locate the H₂O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

Notsu

Nomura

Ishimoto

et al. 2017

ApJ

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“…The CO 2 ice content in the outer disk can be orders of magnitude higher. Both chemical models and measurements of comets show that the CO 2 content in ices can be more than 20% of the total ice content (Le Roy et al 2015;Eistrup et al 2016), with CO 2 ice even becoming more abundant than H 2 O ice in some models of outer disk chemistry (Drozdovskaya et al 2016). This translates into an abundance up to a few × 10 −5 .…”

Section: Tracing the Co 2 Icelinementioning

confidence: 99%

CO₂ infrared emission as a diagnostic of planet-forming regions of disks

Bosman

Bruderer

Dishoeck

2017

A&A

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Context. The infrared ro-vibrational emission lines from organic molecules in the inner regions of protoplanetary disks are unique probes of the physical and chemical structure of planet forming regions and the processes that shape them. These observed lines are mostly interpreted with local thermal equilibrium (LTE) slab models at a single temperature. Aims. The non-LTE excitation effects of carbon dioxide (CO 2 ) are studied in a full disk model to evaluate: (i) what the emitting regions of the different CO 2 ro-vibrational bands are; (ii) how the CO 2 abundance can be best traced using CO 2 ro-vibrational lines using future JWST data and; (iii) what the excitation and abundances tell us about the inner disk physics and chemistry. CO 2 is a major ice component and its abundance can potentially test models with migrating icy pebbles across the iceline. Methods. A full non-LTE CO 2 excitation model has been built starting from experimental and theoretical molecular data. The characteristics of the model are tested using non-LTE slab models. Subsequently the CO 2 line formation has been modelled using a two-dimensional disk model representative of T-Tauri disks where CO 2 is detected in the mid-infrared by the Spitzer Space Telescope. Results. The CO 2 gas that emits in the 15 µm and 4.5 µm regions of the spectrum is not in LTE and arises in the upper layers of disks, pumped by infrared radiation. The v 2 15 µm feature is dominated by optically thick emission for most of the models that fit the observations and increases linearly with source luminosity. Its narrowness compared with that of other molecules stems from a combination of the low rotational excitation temperature (∼ 250 K) and the inherently narrower feature for CO 2 . The inferred CO 2 abundances derived for observed disks range from 3 × 10 −9 to 1 × 10 −7 with respect to total gas density for typical gas/dust ratios of 1000, similar to earlier LTE disk estimates. Line-to-continuum ratios are low, of order a few %, stressing the need for high signal-to-noise (S /N > 300) observations for individual line detections. Conclusions. The inferred CO 2 abundances are much lower than those found in interstellar ices (∼ 10 −5 ), indicating a reset of the chemistry by high temperature reactions in the inner disk. JWST-MIRI with its higher spectral resolving power will allow a much more accurate retrieval of abundances from individual P− and R−branch lines, together with the 13 CO 2 Q-branch at 15 µm. The 13 CO 2 Q-branch is particularly sensitive to possible enhancements of CO 2 due to sublimation of migrating icy pebbles at the iceline(s). Prospects for JWST-NIRSpec are discussed as well.

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“…This result has been confirmed by physical-chemical modeling of the source, which was able to reproduce, among other lines, spatially resolved ALMA data and atomic carbon lines Schwarz et al 2016). This result is interpreted as chemical evolution, that is, carbon has been turned from CO into more complex species either in the gas or in the ice (Aikawa et al 1996;Bergin et al 2014;Drozdovskaya et al 2015;Eistrup et al 2016), or alternatively, as a grain growth effect, carbon has been locked up in large icy bodies that no longer participate in the gas-phase chemistry (Du et al 2015;Kama et al 2016), resulting in less bright CO lines. This hints at the possible existence of a class of disks where CO is not the main carbon reservoir.…”

Section: Introductionmentioning

confidence: 99%

Lupus disks with faint CO isotopologues: low gas/dust or high carbon depletion?

Miotello

Dishoeck

Williams

et al. 2017

A&A

196

285

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Context. An era has started in which gas and dust can be observed independently in protoplanetary disks, thanks to the recent surveys with the Atacama Large Millimeter/sub-millimeter Array (ALMA). The first near-complete high-resolution disk survey in both dust and gas in a single star-forming region has been carried out in Lupus, finding surprisingly low gas-to-dust ratios. Aims. The goal of this work is to fully exploit CO isotopologue observations in Lupus, comparing them with physical-chemical model results, in order to obtain gas masses for a large number of disks and compare gas and dust properties. Methods. We have employed the grid of physical-chemical models presented previously to analyze continuum and CO isotopologue ( 13 CO J = 3−2 and C 18 O J = 3−2) observations of Lupus disks, including isotope-selective processes and freeze-out. We also employed the ALMA 13 CO-only detections to calculate disk gas masses for a total of 34 sources, which expands the sample of 10 disks reported earlier, where C 18 O was also detected. Results. We confirm that overall gas-masses are very low, often lower than 1M J , when volatile carbon is not depleted. Accordingly, global gas-to-dust ratios are much lower than the expected interstellar-medium value of 100, which is predominantly between 1 and 10. Low CO-based gas masses and gas-to-dust ratios may indicate rapid loss of gas, or alternatively chemical evolution, for example, through sequestering of carbon from CO to more complex molecules, or carbon locked up in larger bodies. Conclusions. Current ALMA observations of 13 CO and continuum emission cannot distinguish between these two hypotheses. We have simulated both scenarios, but chemical model results do not allow us to rule out one of the two, pointing to the need to calibrate CO-based masses with other tracers. Assuming that all Lupus disks have evolved mainly as a result of viscous processes over the past few Myr, the previously observed correlation between the current mass accretion rate and dust mass implies a constant gas-to-dust ratio, which is close to 100 based on the observed M disk /Ṁ acc ratio. This in turn points to a scenario in which carbon depletion is responsible for the low luminosities of the CO isotopologue line.

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Setting the volatile composition of (exo)planet-building material

Cited by 160 publications

References 80 publications

Candidate Water Vapor Lines to Locate the H₂O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

Candidate Water Vapor Lines to Locate the H₂O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

CO₂ infrared emission as a diagnostic of planet-forming regions of disks

Lupus disks with faint CO isotopologues: low gas/dust or high carbon depletion?

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Setting the volatile composition of (exo)planet-building material

Cited by 160 publications

References 80 publications

Candidate Water Vapor Lines to Locate the H2O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

Candidate Water Vapor Lines to Locate the H2O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

CO2 infrared emission as a diagnostic of planet-forming regions of disks

Lupus disks with faint CO isotopologues: low gas/dust or high carbon depletion?

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Candidate Water Vapor Lines to Locate the H₂O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

Candidate Water Vapor Lines to Locate the H₂O Snowline Through High-dispersion Spectroscopic Observations. II. The Case of a Herbig Ae Star

CO₂ infrared emission as a diagnostic of planet-forming regions of disks