X-ray group and cluster mass profiles in MOND: unexplained mass on the group scale
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Publication Details
Author list: Angus GW, Famaey B, Buote DA
Publisher: Oxford University Press
Place: OXFORD
Publication year: 2008
Journal: Monthly Notices of the Royal Astronomical Society (0035-8711)
Journal acronym: MON NOT R ASTRON SOC
Volume number: 387
Issue number: 4
Start page: 1470
End page: 1480
Number of pages: 11
ISSN: 0035-8711
eISSN: 1365-2966
Languages: English-Great Britain (EN-GB)
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Abstract
Although very successful in explaining the observed conspiracy between the baryonic distribution and the gravitational field in spiral galaxies without resorting to dark matter (DM), the modified Newtonian dynamics (MOND) paradigm still requires DM in X-ray bright systems. Here, to get a handle on the distribution and importance of this DM, and thus on its possible form, we deconstruct the mass profiles of 26 X-ray emitting systems in MOND, with temperatures ranging from 0.5 to 9 keV. Initially, we compute the MOND dynamical mass as a function of radius, then subtract the known gas mass along with a component of galaxies which include the cD galaxy with M/L-K = 1. Next, we test the compatibility of the required DM with ordinary massive neutrinos at the experimental limit of detection (m(nu) = 2 eV), with density given by the Tremaine-Gunn limit. Even by considering that the neutrino density stays constant and maximal within the central 100 or 150 kpc (which is the absolute upper limit of a possible neutrino contribution there), we show that these neutrinos can never account for the required DM within this region. The natural corollary of this finding is that, whereas clusters (T greater than or similar to 3 ke V) might have most of their mass accounted for if ordinary neutrinos have a 2 eV mass, groups (T less than or similar to 2 keV) cannot be explained by a 2 eV neutrino contribution. This means that, for instance, cluster baryonic dark matter (CBDM, Milgrom) or even sterile neutrinos would present a more satisfactory solution to the problem of missing mass in MOND X-ray emitting systems.
Keywords
Dark matter, galaxies : clusters : general, gravitation
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