The shape of dark matter haloes in the Aquarius simulations: Evolution and memory

Type Conference Paper
Names C. A. Vera-Ciro, L. V. Sales, A. Helmi
Proceedings Title EPJ Web of Conferences
Conference Name Assembling the Puzzle of the Milky Way
Place Le Grand-Bomand, France
Volume 19
Pages 01009
Date February 1, 2012
DOI 10.1051/epjconf/20121901009
Short Title The shape of dark matter haloes in the Aquarius simulations
URL http://adsabs.org/2012EPJWC.1901009V
Library Catalog labs.adsabs.harvard.edu
Abstract We use the high resolution cosmological N-body simulations from the Aquarius project to investigate in detail the mechanisms that determine the shape of Milky Way-type dark matter haloes. We find that, when measured at the instantaneous virial radius, the shape of individual haloes changes with time, evolving from a typically prolate configuration at early stages to a more triaxial/oblate geometry at the present day. This evolution in halo shape correlates well with the distribution of the infalling material: prolate configurations arise when haloes are fed through narrow filaments, which characterizes the early epochs of halo assembly, whereas triaxial/oblate configurations result as the accretion turns more isotropic at later times. Interestingly, at redshift z = 0, clear imprints of the past history of each halo are recorded in their shapes at different radii, which also exhibit a variation from prolate in the inner regions to triaxial/oblate in the outskirts. Provided that the Aquarius haloes are fair representatives of Milky Way-like 1012M⊙ objects, we conclude that the shape of such dark matter haloes is a complex, time-dependent property, with each radial shell retaining memory of the conditions at the time of collapse.
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