Abstract

Abstract We describe how a simple class of out-of-equilibrium, rotating, and asymmetrical mass distributions evolve under their self-gravity to produce a quasi-planar spiral structure surrounding a virialized core, qualitatively resembling a spiral galaxy. The spiral structure is transient, but can survive tens of dynamical times, and further reproduces qualitatively noted features of spiral galaxies such as the predominance of trailing two-armed spirals and large pitch angles. As our models are highly idealized, a detailed comparison with observations is not appropriate, but generic features of the velocity distributions can be identified to be the potential observational signatures of such a mechanism. Indeed, the mechanism leads generically to a characteristic transition from predominantly rotational motion, in a region outside the core, to radial ballistic motion in the outermost parts. Such radial motions are excluded in our Galaxy up to 15 kpc, but could be detected at larger scales in the future by GAIA. We explore the apparent motions seen by external observers of the velocity distributions of our toy galaxies, and find that it is difficult to distinguish them from those of a rotating disk with sub-dominant radial motions at levels typically inferred from observations. These simple models illustrate the possibility that the observed apparent motions of spiral galaxies might be explained by non-trivial non-stationary mass and velocity distributions without invoking a dark matter halo or modification of Newtonian gravity. In this scenario the observed phenomenological relation between the centripetal and gravitational acceleration of the visible baryonic mass could have a simple explanation.

Highlights

  • The arms of spiral galaxies are one of the most striking and remarkable features of the visible universe revealed by astronomy

  • In this paper we show how mass distributions qualitatively resembling those of the visible components of spiral galaxies can result from the far out-of-equilibrium dynamics of purely self-gravitating systems, starting from a class of very simple idealized initial conditions

  • We study in particular the generic features of the velocity distributions of the structures produced by this mechanism, and consider their qualitative compatibility with observations of motions in spiral galaxies

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Summary

Introduction

The arms of spiral galaxies are one of the most striking and remarkable features of the visible universe revealed by astronomy. Several competing theories have been advanced to explain their physical origin, but no single one has emerged definitively as the correct framework (see, e.g., Dobbs & Baba 2014) Understanding their motions is of particular importance because it is the observed apparent (i.e., on the line of sight —LOS) motions in the outer parts of spiral galaxies that have led to the supposition that much of the gravitating matter in them is not visible (Rubin 1983). Two of us have recently studied (Benhaiem & Sylos Labini 2015, 2017) the evolution from configurations that are initially ellipsoidal or of an irregular shape and found them to give rise to a virialized central core surrounded by very flattened configurations made by both weakly bound and ejected particles These results, combined, have led us to the idea that, with some initial rotational motion, it might be possible to generate a spiral structure from these kinds of initial conditions. In the Appendix we detail how we constructed the projected velocity maps from our simulated mass distributions

Simulations
Three-dimensional Properties
Characteristic of Spiral Arms
Apparent Velocity Maps
Discussion
Principal Axes
Orientation of the Observer
Determination of Projected Velocities
One-dimensional Apparent Velocity Profiles
Velocities for Rotating Disk Model
Fitting to a Rotating Disk Model

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