Hydrostatic Equilibrium Does Not Solve the C<sup>18</sup>O Flux Problem in Protoplanetary Disks-Reference-Cited by-同舟云学术

Hydrostatic Equilibrium Does Not Solve the C¹⁸O Flux Problem in Protoplanetary Disks

Published:2022-09-02 Issue:9 Volume:6 Page:176
ISSN:2515-5172
Container-title:Research Notes of the AAS
language:
Short-container-title:Res. Notes AAS

Author:

Bosman Arthur D.^ORCID,Trapman Leon^ORCID,Sturm Ardjan^ORCID,Bergin Edwin A.^ORCID,Booth Alice S.^ORCID,Calahan Jenny K.^ORCID,van Dishoeck Ewine F.^ORCID,McClure Melissa K.^ORCID,Miotello Anna^ORCID,Zhang Ke^ORCID

Abstract

Abstract ALMA observations have shown that there is discrepancy between the disk mass estimate from CO emission and disk masses estimated from other tracers. This discrepancy has been interpreted as lower than expected CO abundance in the warm, surface layers of the disk. Recent work by Ruaud et al. claims that the low observed C18O fluxes can be explained with a ISM abundance of CO, that is 10−4 w.r.t. H2 by including hydrostatic equilbrium in the model density setup. We show that the Ruaud et al. low CO fluxes are due to an unrealistic temperature structure in the outer disk, due to an interaction of their dust model and hydrostatic equilibrium at their inner model edge. Furthermore, we show with our own modeling that a parametric model does a better job at matching the measured outer disk temperature structure.

Publisher

American Astronomical Society

Subject

General Medicine

Link

https://iopscience.iop.org/article/10.3847/2515-5172/ac8e69/pdf

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