Reference : CO Gas Inside the Protoplanetary Disk Cavity in HD 142527: Disk Structure from ALMA
 Document type : Scientific journals : Article Discipline(s) : Physical, chemical, mathematical & earth Sciences : Space science, astronomy & astrophysics To cite this reference: http://hdl.handle.net/2268/182120
 Title : CO Gas Inside the Protoplanetary Disk Cavity in HD 142527: Disk Structure from ALMA Language : English Author, co-author : Perez, S. [> >] Casassus, S. [> >] Ménard, F. [> >] Roman, P. [> >] van der Plas, G. [> >] Cieza, L. [> >] Pinte, C. [> >] Christiaens, Valentin [Universidad de Chile > Departamento de Astronomia > Millenium ALMA Disk Nucleus > Form. doct. sc. (astronomia) >] Hales, A. S. [> >] Publication date : 29-Dec-2014 Journal title : Astrophysical Journal Publisher : IOP Publishing Volume : 798 Pages : 85 Peer reviewed : Yes (verified by ORBi) Audience : International ISSN : 0004-637X e-ISSN : 1538-4357 City : Bristol Country : United Kingdom Keywords : [en] protoplanetary disks ; stars: individual: HD 142527 Abstract : [en] Inner cavities and annular gaps in circumstellar disks are possible signposts of giant planet formation. The young star HD 142527 hosts a massive protoplanetary disk with a large cavity that extends up to 140 AU from the central star, as seen in continuum images at infrared and millimeter wavelengths. Estimates of the survival of gas inside disk cavities are needed to discriminate between clearing scenarios. We present a spatially and spectrally resolved carbon monoxide isotopologue 2-1 line of $^12$CO, $^13$CO, and C[SUP]18[/SUP]$O obtained with the Atacama Large Millimeter/submillimeter Array (ALMA). We detect emission coming from inside the dust-depleted cavity in all three isotopologues. Based on our analysis of the gas in the dust cavity, the$^12$CO emission is optically thick, while$^13$CO and C[SUP]18[/SUP]$O emissions are both optically thin. The total mass of residual gas inside the cavity is \~1.5-2 M $_Jup$. We model the gas with an axisymmetric disk model. Our best-fit model shows that the cavity radius is much smaller in CO than it is in millimeter continuum and scattered light observations, with a gas cavity that does not extend beyond 105 AU (at 3$\sigma$). The gap wall at its outer edge is diffuse and smooth in the gas distribution, while in dust continuum it is manifestly sharper. The inclination angle, as estimated from the high velocity channel maps is 28 \plusmn 0.5 deg, higher than in previous estimates, assuming a fix central star mass of 2.2 M $_&sun;$. Permalink : http://hdl.handle.net/2268/182120 DOI : 10.1088/0004-637X/798/2/85 Other URL : http://adsabs.harvard.edu/abs/2015ApJ...798...85P http://arxiv.org/abs/1410.8168

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