Kinematic deprojection and mass inversion of spherical systems of known
  velocity anisotropy

Alard; Ascasibar; Bicknell; Binney; Biviano; Blumenthal; Cretton; de Lorenzi; Dejonghe; Dejonghe; Dekel; Diemand; Emsellem; Fukushige; Gary A. Mamon; Gerhard; Gnedin; Gwenaël Boué; Hansen; Hansen; Humphrey; Hénon; Jing; Kalal; Kazantzidis; Lupton; Mamon; Mamon; Mamon; Mamon; Merritt; Merritt; Moore; Navarro; Navarro; Osipkov; Prugniel; Richstone; Richstone; Romanowsky; Saha; Sanchis; Schwarzschild; Solanes; Stoehr; Stoehr; Syer; Thomas; Tiret; Tonry; Tormen; Tremaine; Valluri; Williams; Wojtak; Wojtak; Wolf; Łokas; Łokas

research

Kinematic deprojection and mass inversion of spherical systems of known velocity anisotropy

Authors: Alard
Ascasibar
Bicknell
Binney
Biviano
Blumenthal
Cretton
de Lorenzi
Dejonghe
Dejonghe
Dekel
Diemand
Emsellem
Fukushige
Gary A. Mamon
Gerhard
Gnedin
Gwenaël Boué
Hansen
Hansen
Humphrey
Hénon
Jing
Kalal
Kazantzidis
Lupton
Mamon
Mamon
Mamon
Mamon
Merritt
Merritt
Moore
Navarro
Navarro
Osipkov
Prugniel
Richstone
Richstone
Romanowsky
Saha
Sanchis
Schwarzschild
Solanes
Stoehr
Stoehr
Syer
Thomas
Tiret
Tonry
Tormen
Tremaine
Valluri
Williams
Wojtak
Wojtak
Wolf
Łokas
Łokas
Publication date: 1 January 2009
Publisher: 'Wiley'
Doi

Abstract

Traditionally, the mass / velocity anisotropy degeneracy (MAD) inherent in the spherical, stationary, non-streaming Jeans equation has been handled by assuming a mass profile and fitting models to the observed kinematical data. Here, the opposite approach is considered: the equation of anisotropic kinematic projection is inverted for known arbitrary anisotropy to yield the space radial velocity dispersion profile in terms of an integral involving the radial profiles of anisotropy and isotropic dynamical pressure. Then, through the Jeans equation, the mass profile is derived in terms of double integrals of observable quantities. Single integral formulas for both deprojection and mass inversion are provided for several simple anisotropy models (isotropic, radial, circular, general constant, Osipkov-Merritt, Mamon-Lokas and Diemand-Moore-Stadel). Tests of the mass inversion on NFW models with these anisotropy models yield accurate results in the case of perfect observational data, and typically better than 70% (in 4 cases out of 5) accurate mass profiles for the sampling errors expected from current observational data on clusters of galaxies. For the NFW model with mildly increasing radial anisotropy, the mass is found to be insensitive to the adopted anisotropy profile at 7 scale radii and to the adopted anisotropy radius at 3 scale radii. This anisotropic mass inversion method is a useful complementary tool to analyze the mass and anisotropy profiles of spherical systems. It provides the practical means to lift the MAD in quasi-spherical systems such as globular clusters, round dwarf spheroidal and elliptical galaxies, as well as groups and clusters of galaxies, when the anisotropy of the tracer is expected to be linearly related to the slope of its density.Comment: Accepted in MNRAS. 19 pages. Minor changes from previous version: Table 1 of nomenclature, some math simplifications, paragraph in Discussion on alternative deprojection method by deconvolution. 19 pages. 6 figure