A Deep Search for Five Molecules in the 49 Ceti Debris Disk

Surprisingly strong CO emission has been observed from more than a dozen debris disks around nearby main-sequence stars. The origin of this CO is unclear, in particular whether it is left over from the protoplanetary disk phase or is second-generation material released from collisions between icy bo...

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Veröffentlicht in:	The Astrophysical journal 2021-11, Vol.921 (1), p.56
Hauptverfasser:	Klusmeyer, Jessica, Hughes, A. Meredith, Matrà, Luca, Flaherty, Kevin, Kóspál, Ágnes, Moór, Attila, Roberge, Aki, Öberg, Karin, Boley, Aaron, White, Jacob, Wilner, David, Ábrahám, Péter
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Schlagworte:	Abundance Astrochemistry Astrophysics Carbon monoxide Chemical composition Collisions Comets Debris Debris disks Detritus Interstellar chemistry Interstellar radiation Main sequence stars Molecular spectroscopy Outgassing Photodissociation Photodissociation of water Planet formation Protoplanetary disks Radiation Radio interferometry Radio telescopes Searching Solar radiation shielding Solar system Submillimeter astronomy
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creator	Klusmeyer, Jessica Hughes, A. Meredith Matrà, Luca Flaherty, Kevin Kóspál, Ágnes Moór, Attila Roberge, Aki Öberg, Karin Boley, Aaron White, Jacob Wilner, David Ábrahám, Péter
description	Surprisingly strong CO emission has been observed from more than a dozen debris disks around nearby main-sequence stars. The origin of this CO is unclear, in particular whether it is left over from the protoplanetary disk phase or is second-generation material released from collisions between icy bodies like debris dust. The primary unexplored avenue for distinguishing the origin of the material is understanding its molecular composition. Here we present a deep search for five molecules (CN, HCN, HCO+, SiO, and CH3OH) in the debris disk around 49 Ceti. We take advantage of the high sensitivity of the Atacama Large Millimeter/submillimeter Array at Band 7 to integrate for 3.2 hr at modest spatial (1′′) and spectral (0.8 km s−1) resolution. Our search yields stringent upper limits on the flux of all surveyed molecular lines, which imply abundances relative to CO that are orders of magnitude lower than those observed in protoplanetary disks and solar system comets, and also those predicted in outgassing models of second-generation material. However, if CI shielding is responsible for extending the lifetime of any CO produced in second-generation collisions as proposed by Kral et al., then the line ratios do not reflect true ice phase chemical abundances but rather imply that CO is shielded by its own photodissociation product, CI, and other molecules are rapidly photodissociated by the stellar and interstellar radiation field.
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subjects	Abundance Astrochemistry Astrophysics Carbon monoxide Chemical composition Collisions Comets Debris Debris disks Detritus Interstellar chemistry Interstellar radiation Main sequence stars Molecular spectroscopy Outgassing Photodissociation Photodissociation of water Planet formation Protoplanetary disks Radiation Radio interferometry Radio telescopes Searching Solar radiation shielding Solar system Submillimeter astronomy
title	A Deep Search for Five Molecules in the 49 Ceti Debris Disk
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