How Far Do They Go? The Outer Structure of Galactic Dark Matter Halos

PRADA, FRANCISCO; KLYPIN, ANATOLY A.; SIMONNEAU, EDUARDO; BETANCORT-RIJO, JUAN; PATIRI, SANTIAGO; GOTTLÖBER, STEFAN; SANCHEZ-CONDE, MIGUEL A.

ASTROPHYSICAL JOURNAL

Año: 2006 vol. 645 p. 1001 - 1011

0004-637X

We study the density profiles of collapsed galaxy-size dark matter halos with masses 10^11 to 5×10^12 M_solar focusing mostly on the halo outer regions from the formal virial radius R_vir up to 5R_vir-7R_vir. We find that isolated halos in this mass range extend well beyond R_vir exhibiting all properties of virialized objects up to 2R_vir-3R_vir: relatively smooth density profiles and no systematic infall velocities. The dark matter halos in this mass range do not grow as one naively may expect through a steady accretion of satellites; i.e., on average there is no mass infall. This is strikingly different from more massive halos, which have large infall velocities outside the virial radius. We provide an accurate fit for the density profile of these isolated galaxy-size halos. For a wide range 0.01R_vir-2R_vir of radii the halo density profiles are fitted with the approximation rho=rho_s exp[-2 n(x^1/n-1)+<rho_m>, where x≡r/r_s, <rho_m> is the mean matter density of the universe, and the index n is in the range n=6-7.5. These profiles do not show a sudden change of behavior beyond the virial radius. For larger radii we combine the statistics of the initial fluctuations with the spherical collapse model to obtain predictions for the mean and most probable density profiles for halos of several masses. The model gives excellent results beyond 2-3 formal virial radii for the most probable profile and qualitatively correct predictions for the mean profile.