Lopsided spiral galaxies

Lopsided spiral galaxies

The light distribution in the disks of many galaxies is ‘lopsided’ with a spatial extent much larger along one half of a galaxy than the other, as seen in M101. Recent observations show that the stellar disk in a typical spiral galaxy is significantly lopsided, indicating asymmetry in the disk mass...

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Bibliographic Details
Published in:Physics reports Vol. 471; no. 2; pp. 75 - 111
Main Authors: Jog, Chanda J., Combes, Francoise
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 01-02-2009
Elsevier
Subjects:
Astrophysics
Exact sciences and technology
Galaxies: Individual: M101
Galaxies: ISM
Galaxies: Kinematics and dynamics
Galaxies: Spiral
Galaxies: Structure
Physics
Galaxies: Individual: M101
98.62.Hr
98.62.Gq
98.62.Dm
98.58.-w
98.52.Nr
Galaxies: ISM
Galaxies: Spiral
Galaxies: Structure
Galaxies: Kinematics and dynamics
Black holes
Star formation
Dynamics
Gravitational instability
Kinematics
Galaxy evolution
Accretion
Spiral arm
Disk galaxies
Mass distribution
Stellar evolution
Milky Way
Galactic structure
Asymmetry
Galaxy structure
Cosmology
Galaxy groups
Spiral galaxies
Tracers
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Summary:The light distribution in the disks of many galaxies is ‘lopsided’ with a spatial extent much larger along one half of a galaxy than the other, as seen in M101. Recent observations show that the stellar disk in a typical spiral galaxy is significantly lopsided, indicating asymmetry in the disk mass distribution. The mean amplitude of lopsidedness is 0.1, measured as the Fourier amplitude of the m = 1 component normalized to the average value. Thus, lopsidedness is common, and hence it is important to understand its origin and dynamics. This is a new and exciting area in galactic structure and dynamics, in contrast to the topic of bars and two-armed spirals ( m = 2 ) which has been extensively studied in the literature. Lopsidedness is ubiquitous and occurs in a variety of settings and tracers. It is seen in both stars and gas, in the outer disk and the central region, in the field and the group galaxies. The lopsided amplitude is higher by a factor of two for galaxies in a group. The lopsidedness has a strong impact on the dynamics of the galaxy, its evolution, the star formation in it, and on the growth of the central black hole and on the nuclear fuelling. We present here an overview of the observations that measure the lopsided distribution, as well as the theoretical progress made so far to understand its origin and properties. The physical mechanisms studied for its origin include tidal encounters, gas accretion and a global gravitational instability. The related open, challenging problems in this emerging area are discussed.
ISSN:0370-1573
1873-6270
DOI:10.1016/j.physrep.2008.12.002