Outflow Driven by a Protoplanet Embedded in the TW Hya Disk

Gas giant planets are formed by gas accretion onto planetary cores in protoplanetary disks. However, direct evidence of this process is still lacking, limiting our understanding of planetary formation processes. During mass accretion, planet-driven outflows may be launched, which could be observable...

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Bibliographic Details
Published inarXiv.org
Main Authors Yoshida, Tomohiro C, Nomura, Hideko, Law, Charles J, Teague, Richard, Shibaike, Yuhito, Furuya, Kenji, Tsukagoshi, Takashi
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 19.07.2024
Subjects
Accretion disks
Emission
Gas giant planets
Morphology
Outflow
Planet formation
Planetary cores
Protoplanetary disks
Protoplanets
Protostars
Radio telescopes
Star formation
Sulfur oxides
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Summary:Gas giant planets are formed by gas accretion onto planetary cores in protoplanetary disks. However, direct evidence of this process is still lacking, limiting our understanding of planetary formation processes. During mass accretion, planet-driven outflows may be launched, which could be observable by shock tracers such as sulfur monoxide (SO). We report the detection of SO gas in the protoplanetary disk around TW Hya in archival Atacama Large Millimeter/sub-millimeter Array (ALMA) observations. The \(\rm SO\ J=8_7 - 7_6\ \) emission line is detected at a \(6\sigma\) significance and localized to the southeast region of the disk with an arc-like morphology. The line center is red-shifted with respect to the systemic velocity by \(\sim5\ \rm km\ s^{-1}\). The starting point of the SO emission is located at a planet-carved dust gap at \(42\) au. We attribute this to an outflow driven by an embedded protoplanet. Indeed, the observed morphology is well reproduced by a ballistic outflow model. The outflow velocity suggests that the outflow launching source has a mass of \(\sim 4 M_\oplus\ (0.012 M_{\rm Jup})\) and the mass-loss rate is \(3\times10^{-8} - 1\times10^{-6}\ M_{\rm Jup}\ {\rm yr^{-1}}\). With the relation of mass-loss and mass-accretion rates established for protostars, we estimated the mass-accretion rate onto the protoplanet to be \(3\times10^{-7} - 1\times10^{-5}\ M_{\rm Jup}\ {\rm yr^{-1}}\), which matches theoretical predictions for a \(\sim 4 M_\oplus\) planet at this separation. The detection of planet-driven outflow provides us a unique opportunity to directly probe the earliest phase of gas giant planet formation.
ISSN:2331-8422