The Astrophysical Journal (Jan 2024)

FAUST. XIV. Probing the Flared Disk in L1527 with Sulfur-bearing Molecules

  • Ziwei E. Zhang,
  • Nami Sakai,
  • Satoshi Ohashi,
  • Nadia M. Murillo,
  • Claire J. Chandler,
  • Brian Svoboda,
  • Cecilia Ceccarelli,
  • Claudio Codella,
  • Luca Cacciapuoti,
  • Ross O’Donoghue,
  • Serena Viti,
  • Yuri Aikawa,
  • Eleonora Bianchi,
  • Paola Caselli,
  • Steven Charnley,
  • Tomoyuki Hanawa,
  • Izaskun Jímenez-Serra,
  • Hauyu Baobab Liu,
  • Laurent Loinard,
  • Yoko Oya,
  • Linda Podio,
  • Giovanni Sabatini,
  • Charlotte Vastel,
  • Satoshi Yamamoto

DOI
https://doi.org/10.3847/1538-4357/ad3921
Journal volume & issue
Vol. 966, no. 2
p. 207

Abstract

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IRAS04368+2557 in L1527 is a Class 0/I protostar with a clear disk-envelope system revealed by previous Atacama Large Millimeter/submillimeter Array (ALMA) observations. In this paper, we discuss the flared structure of this source with observed sulfur-bearing molecules included in the FAUST ALMA large program. The analyses of molecular distributions and kinematics have shown that CS, SO, and OCS trace different regions of the disk-envelope system. To evaluate the temperature across the disk, we derive rotation temperature with the two observed SO lines. The temperature profile shows a clear, flared “butterfly” structure with the higher temperature being ∼50 K and the central lower temperature region (<30 K) coinciding with the continuum peak, suggesting dynamically originated heating rather than radiation heating from the central protostar. Other physical properties, including column densities, are also estimated and further used to demonstrate the vertical structure of the disk-envelope system. The “warped” disk structure of L1527 is confirmed with our analyses, showing that sulfur-bearing molecules are not only effective material probes but also sufficient for structural studies of protostellar systems.

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