The key planet-formation processes in protoplanetary disks remain an active matter of research. One promising mechanism to radially and azimuthally trap millimeter-emitting dust grains, enabling them to concentrate and grow into planetesimals, is anticyclonic vortices. While dust observations have revealed crescent structures in several disks, observations of their kinematic signatures are still lacking. Studying the gas dynamics is, however, essential to confirm the presence of a vortex and understand its dust trapping properties. In this work, we make use of the high-resolution and sensitivity observations conducted by the exoALMA large program to search for such signatures in the 12CO and 13CO molecular line emission of four disks with azimuthal dust asymmetries: HD 135344B, HD 143006, HD 34282, and MWC 758. To assess the vortex features, we constructed an analytical vortex model and performed hydrodynamical simulations. For the latter, we assumed two scenarios: a vortex triggered at the edge of a dead zone and of a gap created by a massive embedded planet. These models reveal a complex kinematical morphology of the vortex. When compared to the data, we find that none of the sources show a distinctive vortex signature around the dust crescents in the kinematics. HD 135344B exhibits a prominent feature similar to the predictions from the simulations, thus making this the most promising target for sensitive follow-up studies at higher resolution and in particular with less abundant molecules at higher resolution and sensitivity to trace closer to the disk midplane.
exoALMA. XVII. Characterizing the Gas Dynamics around Dust Asymmetries / L. Wolfer, M. Barraza-Alfaro, R. Teague, P. Curone, M. Benisty, M. Fukagawa, J. Bae, G. Cataldi, I. Czekala, S. Facchini, D. Fasano, M. Flock, M. Galloway-Sprietsma, H. Garg, C. Hall, J. Huang, J.D. Ilee, A.F. Izquierdo, K. Kanagawa, G. Lesur, C. Longarini, R.A. Loomis, F. Menard, A. Nath, R. Orihara, C. Pinte, D.J. Price, G. Rosotti, J. Stadler, G. Wafflard-Fernandez, A.J. Winter, H.-. Yen, T.C. Yoshida, B. Zawadzki. - In: THE ASTROPHYSICAL JOURNAL LETTERS. - ISSN 2041-8205. - 984:1(2025 May 01), pp. L22.1-L22.14. [10.3847/2041-8213/adc42c]
exoALMA. XVII. Characterizing the Gas Dynamics around Dust Asymmetries
P. Curone;S. Facchini;C. Longarini;G. Rosotti;
2025
Abstract
The key planet-formation processes in protoplanetary disks remain an active matter of research. One promising mechanism to radially and azimuthally trap millimeter-emitting dust grains, enabling them to concentrate and grow into planetesimals, is anticyclonic vortices. While dust observations have revealed crescent structures in several disks, observations of their kinematic signatures are still lacking. Studying the gas dynamics is, however, essential to confirm the presence of a vortex and understand its dust trapping properties. In this work, we make use of the high-resolution and sensitivity observations conducted by the exoALMA large program to search for such signatures in the 12CO and 13CO molecular line emission of four disks with azimuthal dust asymmetries: HD 135344B, HD 143006, HD 34282, and MWC 758. To assess the vortex features, we constructed an analytical vortex model and performed hydrodynamical simulations. For the latter, we assumed two scenarios: a vortex triggered at the edge of a dead zone and of a gap created by a massive embedded planet. These models reveal a complex kinematical morphology of the vortex. When compared to the data, we find that none of the sources show a distinctive vortex signature around the dust crescents in the kinematics. HD 135344B exhibits a prominent feature similar to the predictions from the simulations, thus making this the most promising target for sensitive follow-up studies at higher resolution and in particular with less abundant molecules at higher resolution and sensitivity to trace closer to the disk midplane.
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