TIPSY: Trajectory of Infalling Particles in Streamers around Young stars
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TIPSY : Trajectory of Infalling Particles in Streamers around Young stars. / Gupta, Aashish; Miotello, Anna; Williams, Jonathan P.; Birnstiel, Til; Kuffmeier, Michael; Yen, Hsi Wei.
In: Astronomy and Astrophysics, Vol. 683, A133, 15.03.2024.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - TIPSY
T2 - Trajectory of Infalling Particles in Streamers around Young stars
AU - Gupta, Aashish
AU - Miotello, Anna
AU - Williams, Jonathan P.
AU - Birnstiel, Til
AU - Kuffmeier, Michael
AU - Yen, Hsi Wei
N1 - Publisher Copyright: © 2024 EDP Sciences. All rights reserved.
PY - 2024/3/15
Y1 - 2024/3/15
N2 - Context. Elongated trails of infalling gas, often referred to as "streamers"have recently been observed around young stellar objects (YSOs) at different evolutionary stages. This asymmetric infall of material can significantly alter star and planet formation processes, especially in the more evolved YSOs. Aims. In order to ascertain the infalling nature of observed streamer-like structures and then systematically characterize their dynamics, we developed the code TIPSY (Trajectory of Infalling Particles in Streamers around Young stars). Methods. Using TIPSY, the streamer molecular line emission is first isolated from the disk emission. Then the streamer emission, which is effectively a point cloud in three-dimensional (3D) position- position- velocity space, is simplified to a curve-like representation. The observed streamer curve is then compared to the theoretical trajectories of infalling material. The best-fit trajectories are used to constrain streamer features, such as the specific energy, the specific angular momenta, the infall timescale, and the 3D morphology. Results. We used TIPSY to fit molecular-line ALMA observations of streamers around a Class II binary system, S CrA, and a Class I/II protostar, HL Tau. Our results indicate that both of the streamers are consistent with infalling motion. For the S CrA streamer, we could constrain the dynamical parameters well and find it to be on a bound elliptical trajectory. On the other hand, the fitting uncertainties are substantially higher for the HL Tau streamer, likely due to the smaller spatial scales of the observations. TIPSY results and mass estimates suggest that S CrA and HL Tau are accreting material at a rate of ≳27 Mjupiter Myr- 1 and ≳5 Mjupiter Myr- 1, respectively, which can significantly increase the mass budget available to form planets. Conclusions. TIPSY can be used to assess whether the morphology and kinematics of observed streamers are consistent with infalling motion and to characterize their dynamics, which is crucial for quantifying their impact on the protostellar systems.
AB - Context. Elongated trails of infalling gas, often referred to as "streamers"have recently been observed around young stellar objects (YSOs) at different evolutionary stages. This asymmetric infall of material can significantly alter star and planet formation processes, especially in the more evolved YSOs. Aims. In order to ascertain the infalling nature of observed streamer-like structures and then systematically characterize their dynamics, we developed the code TIPSY (Trajectory of Infalling Particles in Streamers around Young stars). Methods. Using TIPSY, the streamer molecular line emission is first isolated from the disk emission. Then the streamer emission, which is effectively a point cloud in three-dimensional (3D) position- position- velocity space, is simplified to a curve-like representation. The observed streamer curve is then compared to the theoretical trajectories of infalling material. The best-fit trajectories are used to constrain streamer features, such as the specific energy, the specific angular momenta, the infall timescale, and the 3D morphology. Results. We used TIPSY to fit molecular-line ALMA observations of streamers around a Class II binary system, S CrA, and a Class I/II protostar, HL Tau. Our results indicate that both of the streamers are consistent with infalling motion. For the S CrA streamer, we could constrain the dynamical parameters well and find it to be on a bound elliptical trajectory. On the other hand, the fitting uncertainties are substantially higher for the HL Tau streamer, likely due to the smaller spatial scales of the observations. TIPSY results and mass estimates suggest that S CrA and HL Tau are accreting material at a rate of ≳27 Mjupiter Myr- 1 and ≳5 Mjupiter Myr- 1, respectively, which can significantly increase the mass budget available to form planets. Conclusions. TIPSY can be used to assess whether the morphology and kinematics of observed streamers are consistent with infalling motion and to characterize their dynamics, which is crucial for quantifying their impact on the protostellar systems.
KW - ISM: kinematics and dynamics
KW - Methods: data analysis
KW - Planets and satellites: formation
KW - Protoplanetary disks
KW - Stars: formation
U2 - 10.1051/0004-6361/202348007
DO - 10.1051/0004-6361/202348007
M3 - Journal article
AN - SCOPUS:85187977399
VL - 683
JO - Astronomy & Astrophysics
JF - Astronomy & Astrophysics
SN - 0004-6361
M1 - A133
ER -
ID: 389364896