Unlocking CO Depletion in Protoplanetary Disks. I. The Warm Molecular Layer

CO is commonly used as a tracer of the total gas mass in both the interstellar medium and in protoplanetary disks. Recently, there has been much debate about the utility of CO as a mass tracer in disks. Observations of CO in protoplanetary disks reveal a range of CO abundances, with measurements of...

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Bibliographic Details
Published inThe Astrophysical journal Vol. 856; no. 1; pp. 85 - 100
Main Authors Schwarz, Kamber R., Bergin, Edwin A., Cleeves, L. Ilsedore, Zhang, Ke, Öberg, Karin I., Blake, Geoffrey A., Anderson, Dana
Format Journal Article
LanguageEnglish
Published Philadelphia The American Astronomical Society 20.03.2018
IOP Publishing
Subjects
Abundance
astrochemistry
Astrophysics
Carbon
circumstellar matter
Cosmic rays
Depletion
Disks
Dust
Grain size distribution
Interstellar gas
Interstellar matter
Interstellar medium
Ionization
ISM: abundances
Mass ratios
molecular data
Organic chemistry
Planet formation
Protoplanetary disks
Protoplanets
Reprocessing
Snowline
Time dependence
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Summary:CO is commonly used as a tracer of the total gas mass in both the interstellar medium and in protoplanetary disks. Recently, there has been much debate about the utility of CO as a mass tracer in disks. Observations of CO in protoplanetary disks reveal a range of CO abundances, with measurements of low CO to dust mass ratios in numerous systems. One possibility is that carbon is removed from CO via chemistry. However, the full range of physical conditions conducive to this chemical reprocessing is not well understood. We perform a systematic survey of the time dependent chemistry in protoplanetary disks for 198 models with a range of physical conditions. We vary dust grain size distribution, temperature, comic-ray and X-ray ionization rates, disk mass, and initial water abundance, detailing what physical conditions are necessary to activate the various CO depletion mechanisms in the warm molecular layer. We focus our analysis on the warm molecular layer in two regions: the outer disk (100 au) well outside the CO snowline and the inner disk (19 au) just inside the midplane CO snowline. After 1 Myr, we find that the majority of models have a CO abundance relative to H2 less than 10−4 in the outer disk, while an abundance less than 10−5 requires the presence of cosmic-rays. Inside the CO snowline, significant depletion of CO only occurs in models with a high cosmic-ray rate. If cosmic-rays are not present in young disks, it is difficult to chemically remove carbon from CO. Additionally, removing water prior to CO depletion impedes the chemical processing of CO. Chemical processing alone cannot explain current observations of low CO abundances. Other mechanisms must also be involved.
Bibliography:AAS08145
Interstellar Matter and the Local Universe
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/aaae08