The SWELLS survey. IV. Precision measurements of the stellar and dark matter distributions in a spiral lens galaxy

Abstract

We construct a fully self-consistent mass model for the lens galaxy J2141 at z=0.14, and use it to improve on previous studies by modelling its gravitational lensing effect, gas rotation curve and stellar kinematics simultaneously. We adopt a very flexible axisymmetric mass model constituted by a generalized NFW dark matter halo and a stellar mass distribution obtained by deprojecting the MGE fit to the high-resolution K'-band LGSAO imaging data of the galaxy, with the (spatially constant) M/L ratio as a free parameter. We model the stellar kinematics by solving the anisotropic Jeans equations. We find that the inner logarithmic slope of the dark halo is weakly constrained (gamma = 0.82+0.65-0.54), and consistent with an unmodified NFW profile. We infer the galaxy to have (i) a dark matter fraction within 2.2 disk radii of 0.28+0.15-0.10, independent of the galaxy stellar population, implying a maximal disk for J2141; (ii) an apparently uncontracted dark matter halo, with concentration c-2 = 7.7-2.5+4.2 and virial velocity vvir = 242-39+44 km/s, consistent with LCDM predictions; (iii) a slightly oblate halo (qh = 0.75+0.27-0.16), consistent with predictions from baryon-affected models. Comparing the stellar mass inferred from the combined analysis (log10 Mstar/Msun = 11.12-0.09+0.05) with that inferred from SPS modelling of the galaxies colours, and accounting for a cold gas fraction of 20+/-10%, we determine a preference for a Chabrier IMF over Salpeter IMF by a Bayes factor of 5.7 (substantial evidence). We infer a value betaz = 1 - sigma2z/sigma2R = 0.43-0.11+0.08 for the orbital anisotropy parameter in the meridional plane, in agreement with most studies of local disk galaxies, and ruling out at 99% CL that the dynamics of this system can be described by a two-integral distribution function. [Abridged]