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Molecular clouds as gravitational instabilities in rotating disks : a modified stability criterion

Sharon Meidt van der Wel (UGent)
(2022) ASTROPHYSICAL JOURNAL. 937(2).
Author
Organization
Abstract
Molecular gas disks are generally Toomre stable (Q ( T ) > 1) and yet clearly gravitationally unstable to structure formation as evidenced by the existence of molecular clouds and ongoing star formation. This paper adopts a 3D perspective to obtain a general picture of instabilities in flattened rotating disks, using the 3D dispersion relation to describe how disks evolve when perturbed over their vertical extents. By explicitly adding a vertical perturbation to an unperturbed equilibrium disk, stability is shown to vary with height above the midplane. Near z = 0, where the equilibrium density is roughly constant, instability takes on a Jeans-like quality, occurring on scales larger than the Jeans length and subject to a threshold Q ( M ) = kappa (2)/(4 pi G rho) = 1 or roughly Q ( T ) approximate to 2. Far from the midplane, on the other hand, stability is pervasive, and the threshold for the total disk (out to z = +/-infinity) to be stabilized is lowered to Q ( T ) = 1 as a consequence. In this new framework, gas disks are able to fragment through partial 3D instability even where total 2D instability is suppressed. The growth rates of the fragments formed via 3D instability are comparable to, or faster than, Toomre instabilities. The rich structure in molecular disks on the scale of tens of parsecs can thus be viewed as a natural consequence of their 3D nature and their exposure to a variety of vertical perturbations acting on roughly a disk scale height, i.e., due to their situation within the more extended galaxy potential, participation in the disk-halo flow, and exposure to star formation feedback.
Keywords
REGULATED STAR-FORMATION, GALACTIC DISCS, SPIRAL MODES, RAM-PRESSURE, GAS, GALAXIES, CO, THRESHOLDS, PARAMETER, RUNAWAY

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MLA
van der Wel, Sharon Meidt. “Molecular Clouds as Gravitational Instabilities in Rotating Disks : A Modified Stability Criterion.” ASTROPHYSICAL JOURNAL, vol. 937, no. 2, 2022, doi:10.3847/1538-4357/ac86ce.
APA
van der Wel, S. M. (2022). Molecular clouds as gravitational instabilities in rotating disks : a modified stability criterion. ASTROPHYSICAL JOURNAL, 937(2). https://doi.org/10.3847/1538-4357/ac86ce
Chicago author-date
Wel, Sharon Meidt van der. 2022. “Molecular Clouds as Gravitational Instabilities in Rotating Disks : A Modified Stability Criterion.” ASTROPHYSICAL JOURNAL 937 (2). https://doi.org/10.3847/1538-4357/ac86ce.
Chicago author-date (all authors)
van der Wel, Sharon Meidt. 2022. “Molecular Clouds as Gravitational Instabilities in Rotating Disks : A Modified Stability Criterion.” ASTROPHYSICAL JOURNAL 937 (2). doi:10.3847/1538-4357/ac86ce.
Vancouver
1.
van der Wel SM. Molecular clouds as gravitational instabilities in rotating disks : a modified stability criterion. ASTROPHYSICAL JOURNAL. 2022;937(2).
IEEE
[1]
S. M. van der Wel, “Molecular clouds as gravitational instabilities in rotating disks : a modified stability criterion,” ASTROPHYSICAL JOURNAL, vol. 937, no. 2, 2022.
@article{01GKMJ73ARGR1GFTSCBGXMAFXM,
  abstract     = {{Molecular gas disks are generally Toomre stable (Q ( T ) > 1) and yet clearly gravitationally unstable to structure formation as evidenced by the existence of molecular clouds and ongoing star formation. This paper adopts a 3D perspective to obtain a general picture of instabilities in flattened rotating disks, using the 3D dispersion relation to describe how disks evolve when perturbed over their vertical extents. By explicitly adding a vertical perturbation to an unperturbed equilibrium disk, stability is shown to vary with height above the midplane. Near z = 0, where the equilibrium density is roughly constant, instability takes on a Jeans-like quality, occurring on scales larger than the Jeans length and subject to a threshold Q ( M ) = kappa (2)/(4 pi G rho) = 1 or roughly Q ( T ) approximate to 2. Far from the midplane, on the other hand, stability is pervasive, and the threshold for the total disk (out to z = +/-infinity) to be stabilized is lowered to Q ( T ) = 1 as a consequence. In this new framework, gas disks are able to fragment through partial 3D instability even where total 2D instability is suppressed. The growth rates of the fragments formed via 3D instability are comparable to, or faster than, Toomre instabilities. The rich structure in molecular disks on the scale of tens of parsecs can thus be viewed as a natural consequence of their 3D nature and their exposure to a variety of vertical perturbations acting on roughly a disk scale height, i.e., due to their situation within the more extended galaxy potential, participation in the disk-halo flow, and exposure to star formation feedback.}},
  articleno    = {{88}},
  author       = {{van der Wel, Sharon Meidt}},
  issn         = {{0004-637X}},
  journal      = {{ASTROPHYSICAL JOURNAL}},
  keywords     = {{REGULATED STAR-FORMATION,GALACTIC DISCS,SPIRAL MODES,RAM-PRESSURE,GAS,GALAXIES,CO,THRESHOLDS,PARAMETER,RUNAWAY}},
  language     = {{eng}},
  number       = {{2}},
  pages        = {{19}},
  title        = {{Molecular clouds as gravitational instabilities in rotating disks : a modified stability criterion}},
  url          = {{http://dx.doi.org/10.3847/1538-4357/ac86ce}},
  volume       = {{937}},
  year         = {{2022}},
}
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