In the past decade, the Atacama Large Millimeter/submillimeter Array (ALMA) has revealed a plethora of substructures in the disks surrounding young stars. These substructures have several proposed formation mechanisms, with one leading theory being the interaction between the disk and newly formed planets. In this Letter, we present high angular resolution ALMA observations of LkCa 15’s disk that reveal a striking difference in dust and CO emission morphology. The dust continuum emission shows a ringlike structure characterized by a dust-depleted inner region of ∼40 au in radius. Conversely, the CO emission is radially smoother and shows no sign of gas depletion within the dust cavity. We compare the observations with models for the disk-planet interaction, including radiative transfer calculation in the dust and CO emission. This source is particularly interesting, as the presence of massive planets within the dust cavity has been suggested based on previous near-IR observations. We find that the level of CO emission observed within the dust cavity is inconsistent with the presence of planets more massive than Jupiter orbiting between 10 and 40 au. Instead, we argue that the LkCa 15 innermost dust cavity might be created either by a chain of low-mass planets or by other processes that do not require the presence of planets.
exoALMA. XI. ALMA Observations and Hydrodynamic Models of LkCa 15: Implications for Planetary Mass Companions in the Dust Continuum Cavity / C.H. Gardner, A. Isella, H. Li, S. Li, J. Bae, M. Barraza-Alfaro, M. Benisty, G. Cataldi, P. Curone, J.A. Eisner, S. Facchini, D. Fasano, M. Flock, K.B. Follette, M. Fukagawa, M. Galloway-Sprietsma, H. Garg, C. Hall, J. Huang, J.D. Ilee, M.J. Ireland, A.F. Izquierdo, C.M. Johns-Krull, K. Kanagawa, A.L. Kraus, G. Lesur, S. Liu, C. Longarini, R.A. Loomis, F. Menard, R. Orihara, C. Pinte, D. Price, L. Ricci, G. Rosotti, S. Sallum, J. Stadler, R. Teague, G. Wafflard-Fernandez, D.J. Wilner, A.J. Winter, L. Wölfer, H. Yen, T.C. Yoshida, B. Zawadzki, Z. Zhu. - In: THE ASTROPHYSICAL JOURNAL LETTERS. - ISSN 2041-8205. - 984:1(2025 May 01), pp. L16.1-L16.18. [10.3847/2041-8213/adc432]
exoALMA. XI. ALMA Observations and Hydrodynamic Models of LkCa 15: Implications for Planetary Mass Companions in the Dust Continuum Cavity
P. Curone;S. Facchini;C. Longarini;G. Rosotti;
2025
Abstract
In the past decade, the Atacama Large Millimeter/submillimeter Array (ALMA) has revealed a plethora of substructures in the disks surrounding young stars. These substructures have several proposed formation mechanisms, with one leading theory being the interaction between the disk and newly formed planets. In this Letter, we present high angular resolution ALMA observations of LkCa 15’s disk that reveal a striking difference in dust and CO emission morphology. The dust continuum emission shows a ringlike structure characterized by a dust-depleted inner region of ∼40 au in radius. Conversely, the CO emission is radially smoother and shows no sign of gas depletion within the dust cavity. We compare the observations with models for the disk-planet interaction, including radiative transfer calculation in the dust and CO emission. This source is particularly interesting, as the presence of massive planets within the dust cavity has been suggested based on previous near-IR observations. We find that the level of CO emission observed within the dust cavity is inconsistent with the presence of planets more massive than Jupiter orbiting between 10 and 40 au. Instead, we argue that the LkCa 15 innermost dust cavity might be created either by a chain of low-mass planets or by other processes that do not require the presence of planets.
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