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On the cross-section of dark matter using substructure infall into galaxy clusters.

Harvey, D. and Tittley, E. and Massey, R. and Kitching, T.D. and Taylor, A. and Pike, S.R. and Kay, S.T. and Lau, E.T. and Nagai, D. (2014) 'On the cross-section of dark matter using substructure infall into galaxy clusters.', Monthly notices of the Royal Astronomical Society., 441 (1). pp. 404-416.

Abstract

We develop a statistical method to measure the interaction cross-section of dark matter, exploiting the continuous minor merger events in which small substructures fall into galaxy clusters. We find that by taking the ratio of the distances between the galaxies and dark matter, and galaxies and gas in accreting subhaloes, we form a quantity that can be statistically averaged over a large sample of systems whilst removing any inherent line-of-sight projections. To interpret this ratio as a cross-section of dark matter, we derive an analytical description of subhalo infall allowing us to constrain self-interaction models in which drag is an appropriate macroscopic treatment. We create mock observations from cosmological simulations of structure formation and find that collisionless dark matter becomes physically separated from X-ray gas by up to ∼20 h−1 kpc. Adding realistic levels of noise, we are able to predict achievable constraints from observational data. Current archival data should be able to detect a difference in the dynamical behaviour of dark matter and standard model particles at 6σ, and measure the total interaction cross-section σ/m with 68 per cent confidence limits of ±1 cm2 g−1. We note that this method is not restricted by the limited number of major merging events and is easily extended to large samples of clusters from future surveys which could potentially push statistical errors to <0.1 cm2 g−1.

Item Type:Article
Keywords:Dark matter.
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Status:Peer-reviewed
Publisher Web site:http://dx.doi.org/10.1093/mnras/stu337
Publisher statement:This article has been accepted for publication in Monthly notices of the Royal Astronomical Society © 2013 The Authors Published by Oxford University Press on behalf of Royal Astronomical Society. All rights reserved.
Record Created:19 Aug 2014 14:05
Last Modified:19 Aug 2014 15:57

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