Mass of Clusters in Simulations

Abstract

We show that dark matter haloes, in n--body simulations, have a boundary layer (BL) with precise features. In particular, it encloses all dynamically stable mass while, outside it, dynamical stability is lost soon. Particles can pass through such BL, which however acts as a confinement barrier for dynamical properties. BL is set by evaluating kinetic and potential energies (T(r) and W(r)) and calculating R=-2T/W. Then, on BL, R has a minimum which closely approaches a maximum of w= -dlog W/dlog r. Such Rw ``requirement'' is consistent with virial equilibrium, but implies further regularities. We test the presence of a BL around haloes in spatially flat CDM simulations, with or without cosmological constant. We find that the mass Mc, enclosed within the radius rc, where the Rw requirement is fulfilled, closely approaches the mass Mdyn, evaluated from the velocities of all particles within rc, according to the virial theorem. Using rc we can then determine an individual density contrast Deltac for each virialized halo, which can be compared with the "virial" density contrast Δv ~178 Ωm0.45 (Omegam: matter density parameter) obtained assuming a spherically symmetric and unperturbed fluctuation growth. The spread in Deltac is wide, and cannot be neglected when global physical quantities related to the clusters are calculated, while the average Deltac is ~25 % smaller than the corresponding Deltav; moreover if Mdyn is defined from the radius linked to Deltav, we have a much worse fit with particle mass then starting from Rw requirement.

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