Mass models of disk galaxies from the DiskMass Survey in MOND

This article explores the agreement between the predictions of Modified Newtonian Dynamics (MOND) and the rotation curves and stellar velocity dispersion profiles measured by the DiskMass Survey. A bulge-disk decomposition was made for each of the thirty published galaxies, and a MOND Poisson solver...

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Bibliographic Details
Published in:arXiv.org 2015-05
Main Authors: Angus, Garry W, Gentile, Gianfranco, Swaters, Robert A, Famaey, Benoit, Diaferio, Antonaldo, McGaugh, Stacy S, Kurt J van der Heyden
Format: Article
Language:English
Subjects:
Acceleration
Astronomical models
Computer simulation
Dark matter
Disk galaxies
Dispersion
Galaxies
Galaxy distribution
Gravitational fields
Inclination
Markov chains
Monte Carlo simulation
Parameters
Personal computers
Stellar mass
Stellar rotation
Vertical distribution
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Summary:This article explores the agreement between the predictions of Modified Newtonian Dynamics (MOND) and the rotation curves and stellar velocity dispersion profiles measured by the DiskMass Survey. A bulge-disk decomposition was made for each of the thirty published galaxies, and a MOND Poisson solver was used to simultaneously compute, from the baryonic mass distributions, model rotation curves and vertical velocity dispersion profiles, which were compared to the measured values. The two main free parameters, the stellar disk's mass-to-light ratio (\(M/L\)) and its exponential scale-height (\(h_z\)), were estimated by Markov Chain Monte Carlo modelling. The average best-fit K-band stellar mass-to-light ratio was \(M/L \simeq 0.55 \pm 0.15\). However, to match the DiskMass Survey data, the vertical scale-heights would have to be in the range \(h_z=200\) to \(400\) pc which is a factor of two lower than those derived from observations of edge-on galaxies with a similar scale-length. The reason is that modified gravity versions of MOND characteristically require a larger \(M/L\) to fit the rotation curve in the absence of dark matter and therefore predict a stronger vertical gravitational field than Newtonian models. It was found that changing the MOND acceleration parameter, the shape of the velocity dispersion ellipsoid, the adopted vertical distribution of stars, as well as the galaxy inclination, within any realistic range, all had little impact on these results.
ISSN:2331-8422