C. Yuan scite author profile

Observations with the Hubble Space Telescope reveal an irregular network of dust spiral arms in the nuclear region of the interacting disk galaxy NGC 2207. The spirals extend from ∼50 to ∼300 pc in galactocentric radius, with a projected width of ∼20 pc. Radiative transfer calculations determine the gas properties of the spirals and the inner disk and imply a factor of ∼4 local gas compression in the spirals. The gas is not strongly self-gravitating, nor is there a nuclear bar, so the spirals could not have formed by the usual mechanisms applied to main galaxy disks. Instead, they may result from acoustic instabilities that amplify at small galactic radii. Such instabilities may promote gas accretion into the nucleus.

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Curvature and Acoustic Instabilities in Rotating Fluid Disks

Montenegro

Yuan

Elmegreen³

1999

ApJ

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The stability of a rotating Ñuid disk to the formation of spiral arms is studied in the tight-winding approximation in the linear regime. The dispersion relation for spirals that was derived by Bertin et al. is shown to contain a new, acoustic instability beyond the Lindblad resonances that depends only on pressure and rotation. In this regime, pressure and gravity exchange roles as drivers and inhibitors of spiral wave structures. Other instabilities that are enhanced by pressure are also found in the general dispersion relation by including higher order terms in the small parameter 1/kr for wavenumber k and radius r. We identify two important dimensionless physical parameters :which is essentially the v \ 2nGp 0 /(ri2), ratio of disk mass to total mass (disk and halo), and a/(ir), which is the ratio of epicyclic radius to disk radius is the mass column density, i is the epicyclic frequency, and a is the sound speed). The small (p 0 term f \ (k2r2 ] m2)~1@2 is an additional parameter that is purely geometrical for number of arms m. When these terms are included in the dispersion relation, the oscillation frequency becomes complex, leading to the growth of perturbations even for large values of ToomreÏs parameter Q. The growth rate is proportional to a linear combination of terms that depend on v and a/(ir). Instabilities that arise from v are termed gravitational-curvature instabilities because v depends on the disk mass and is largest when the radius is small, i.e., when the orbital curvature is large. Instabilities that arise from a/(ir) are termed acoustic-curvature instabilities because they arise from only the pressure terms at small r. Unstable growth rates are determined for these instabilities in four cases : a self-gravitating disk with a Ñat rotation curve, a self-gravitating disk with solid body rotation, a nonÈself-gravitating disk with solid body rotation, and a nonÈself-gravitating disk with Keplerian rotation. The most important application appears to be as a source of spiral structure, possibly leading to accretion in nonÈself-gravitating disks, such as some galactic nuclear disks, disks around black holes, and protoplanetary disks. All of these examples have short orbital times so the unstable growth time can be small, even when only terms of order v contribute.

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Application of the Densiity-Wave Theory to the Spiral Structure of the Milky way System. I. Systematic Motion of Neutral Hydrogen

Yuan¹

1969

ApJ

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C. Yuan

On the Spiral Structure of Disk Galaxies. III. Comparison with Observations

Dust Spirals and Acoustic Noise in the Nucleus of the Galaxy NGC 2207

Curvature and Acoustic Instabilities in Rotating Fluid Disks

Application of the Densiity-Wave Theory to the Spiral Structure of the Milky way System. I. Systematic Motion of Neutral Hydrogen

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