exoALMA. XII. Weighing and Sizing exoALMA Disks with Rotation Curve Modelling

Longarini, C.; Lodato, G.; Rosotti, G.; Andrews, S.; Winter, A.; Stadler, J.; Izquierdo, A.; Galloway-Sprietsma, M.; Facchini, S.; Curone, P.; Benisty, M.; Teague, R.; Bae, J.; Barraza-Alfaro, M.; Cataldi, G.; Czekala, I.; Cuello, N.; Fasano, D.; Flock, M.; Fukagawa, M.; Garg, H.; Hall, C.; Hammond, I.; Hardiman, C.; Hilder, T.; Huang, J.; Ilee, J.D.; Isella, A.; Kanagawa, K.; Lesur, G.; Loomis, R.A.; Menard, F.; Orihara, R.; Pinte, C.; Price, D.; Testi, L.; Fernandez, G.W.; Wolfer, L.; Yen, H.-.; Yoshida, T.C.; Zawadzki, B.

doi:10.3847/2041-8213/adc431

The exoALMA large program offers a unique opportunity to investigate the fundamental properties of protoplanetary disks, such as their masses and sizes, providing important insights into the mechanism responsible for the transport of angular momentum. In this work, we model the rotation curves of CO isotopologues 12CO and 13CO of 10 sources within the exoALMA sample, and we constrain the stellar mass, the disk mass, and the density scale radius through precise characterization of the pressure gradient and disk self-gravity. We obtain dynamical disk masses for our sample by measuring the self-gravitating contribution to the gravitational potential. We are able to parametrically describe their surface density, and all of them appear gravitationally stable. By combining dynamical disk masses with dust continuum emission data, we determine an averaged gas-to-dust ratio of approximately 400, not statistically consistent with the standard value of 100, assuming optically thin dust emission. In addition, the measurement of the dynamical scale radius allows for direct comparison with flux-based radii of gas and dust. This comparison suggests that substructures may influence the size of the dust disk and that CO depletion might reconcile our measurements with thermochemical models. Finally, with the stellar mass, disk mass, scale radius, and accretion rate, and assuming self-similar evolution of the surface density, we constrain the effective αS for these systems. We find a broad range of αS values ranging between 10−5 and 10−2

exoALMA. XII. Weighing and Sizing exoALMA Disks with Rotation Curve Modelling / C. Longarini, G. Lodato, G. Rosotti, S. Andrews, A. Winter, J. Stadler, A. Izquierdo, M. Galloway-Sprietsma, S. Facchini, P. Curone, M. Benisty, R. Teague, J. Bae, M. Barraza-Alfaro, G. Cataldi, I. Czekala, N. Cuello, D. Fasano, M. Flock, M. Fukagawa, H. Garg, C. Hall, I. Hammond, C. Hardiman, T. Hilder, J. Huang, J.D. Ilee, A. Isella, K. Kanagawa, G. Lesur, R.A. Loomis, F. Menard, R. Orihara, C. Pinte, D. Price, L. Testi, G.W. Fernandez, L. Wolfer, H.-. Yen, T.C. Yoshida, B. Zawadzki. - In: THE ASTROPHYSICAL JOURNAL LETTERS. - ISSN 2041-8205. - 984:1(2025 May 01), pp. L17.1-L17.20. [10.3847/2041-8213/adc431]

exoALMA. XII. Weighing and Sizing exoALMA Disks with Rotation Curve Modelling

C. Longarini^Primo;G. Lodato^Secondo;G. Rosotti;Andrews S.;Winter A.;Stadler J.;Izquierdo A.;Galloway-Sprietsma M.;S. Facchini;P. Curone;Benisty M.;Teague R.;Bae J.;Barraza-Alfaro M.;Cataldi G.;Czekala I.;Cuello N.;Fasano D.;Flock M.;Fukagawa M.;Garg H.;Hall C.;Hammond I.;Hardiman C.;Hilder T.;Huang J.;Ilee J. D.;Isella A.;Kanagawa K.;Lesur G.;Loomis R. A.;Menard F.;Orihara R.;Pinte C.;Price D.;Testi L.;Fernandez G. W.;Wolfer L.;Yen H. -W.;Yoshida T. C.;Zawadzki B.

2025

Abstract

The exoALMA large program offers a unique opportunity to investigate the fundamental properties of protoplanetary disks, such as their masses and sizes, providing important insights into the mechanism responsible for the transport of angular momentum. In this work, we model the rotation curves of CO isotopologues 12CO and 13CO of 10 sources within the exoALMA sample, and we constrain the stellar mass, the disk mass, and the density scale radius through precise characterization of the pressure gradient and disk self-gravity. We obtain dynamical disk masses for our sample by measuring the self-gravitating contribution to the gravitational potential. We are able to parametrically describe their surface density, and all of them appear gravitationally stable. By combining dynamical disk masses with dust continuum emission data, we determine an averaged gas-to-dust ratio of approximately 400, not statistically consistent with the standard value of 100, assuming optically thin dust emission. In addition, the measurement of the dynamical scale radius allows for direct comparison with flux-based radii of gas and dust. This comparison suggests that substructures may influence the size of the dust disk and that CO depletion might reconcile our measurements with thermochemical models. Finally, with the stellar mass, disk mass, scale radius, and accretion rate, and assuming self-similar evolution of the surface density, we constrain the effective αS for these systems. We find a broad range of αS values ranging between 10−5 and 10−2

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				Settore PHYS-05/A - Astrofisica, cosmologia e scienza dello spazio
			
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									Unveiling the infancy of planetary systems (UNVEIL)
								
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									UNVEIL
								
	Nome finanziatore
	
										EUROPEAN COMMISSION
									
	N. Contratto
	
									101076613
								
	Titolo Progetto
	
									Probing the Origin of Planetary Systems (POPS)
								
	Acronimo
	
									POPS
								
	Nome finanziatore
	
										MINISTERO DELL'UNIVERSITA' E DELLA RICERCA
									
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									2022YP5ACE_001
								
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									Dust and gas in planet forming discs (DUSTBUSTER)
								
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									DUSTBUSTER
								
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										EUROPEAN COMMISSION
									
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									H2020
								
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									823823
								
	Titolo Progetto
	
									From non-ideal magnetohydrodynamics to the structure and evolution of protoplanetary discs
								
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									MHDiscs
								
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										European Commission
									
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									Horizon 2020 Framework Programme
								
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									815559
								
	Titolo Progetto
	
									Establishing a global observational view of the early stages of planet formation and evolution
								
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									PROTOPLANETS
								
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										European Commission
									
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									Horizon 2020 Framework Programme
								
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									101002188
								
	Titolo Progetto
	
									A new window into planet formation: disc kinematics
								
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										FONDAZIONE CARIPLO
									
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									ID Progetto 2022-1217
								
	Data di pubblicazione
	
				1-mag-2025
			
	Data ahead of print o data di stampa
	
				28-apr-2025
			
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				THE ASTROPHYSICAL JOURNAL LETTERS
			
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				Institute of Physics (IOP) Publishing : University of Chicago Press : American Astronomical Society
			
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				984
			
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				https://dx.doi.org/10.3847/2041-8213/adc431
			
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				WOS:001478019500001
			
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				2-s2.0-105004239671
			
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				info:eu-repo/semantics/article
			
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				exoALMA. XII. Weighing and Sizing exoALMA Disks with Rotation Curve Modelling / C. Longarini, G. Lodato, G. Rosotti, S. Andrews, A. Winter, J. Stadler, A. Izquierdo, M. Galloway-Sprietsma, S. Facchini, P. Curone, M. Benisty, R. Teague, J. Bae, M. Barraza-Alfaro, G. Cataldi, I. Czekala, N. Cuello, D. Fasano, M. Flock, M. Fukagawa, H. Garg, C. Hall, I. Hammond, C. Hardiman, T. Hilder, J. Huang, J.D. Ilee, A. Isella, K. Kanagawa, G. Lesur, R.A. Loomis, F. Menard, R. Orihara, C. Pinte, D. Price, L. Testi, G.W. Fernandez, L. Wolfer, H.-. Yen, T.C. Yoshida, B. Zawadzki. - In: THE ASTROPHYSICAL JOURNAL LETTERS. - ISSN 2041-8205. - 984:1(2025 May 01), pp. L17.1-L17.20. [10.3847/2041-8213/adc431]
			
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						C. Longarini, G. Lodato, G. Rosotti, S. Andrews, A. Winter, J. Stadler, A. Izquierdo, M. Galloway-Sprietsma, S. Facchini, P. Curone, M. Benisty, R. Te...espandi
						
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