The SAMI Galaxy Survey: mass-kinematics scaling relations
arXiv:1905.12637 · doi:10.1093/mnras/stz1439
Abstract
We use data from the Sydney-AAO Multi-object Integral-field spectroscopy (SAMI) Galaxy Survey to study the dynamical scaling relation between galaxy stellar mass $M_*$ and the general kinematic parameter $S_K = \sqrt{K V_{rot}^2 + Ï^2}$ that combines rotation velocity $V_{rot}$ and velocity dispersion $Ï$. We show that the $\log M_* - \log S_K$ relation: (1)~is linear above limits set by properties of the samples and observations; (2)~has slightly different slope when derived from stellar or gas kinematic measurements; (3)~applies to both early-type and late-type galaxies and has smaller scatter than either the Tully-Fisher relation ($\log M_* - \log V_{rot}$) for late types or the Faber-Jackson relation ($\log M_* - \logÏ$) for early types; and (4)~has scatter that is only weakly sensitive to the value of $K$, with minimum scatter for $K$ in the range 0.4 and 0.7. We compare $S_K$ to the aperture second moment (the `aperture velocity dispersion') measured from the integrated spectrum within a 3-arcsecond radius aperture ($Ï_{3^{\prime\prime}}$). We find that while $S_{K}$ and $Ï_{3^{\prime\prime}}$ are in general tightly correlated, the $\log M_* - \log S_K$ relation has less scatter than the $\log M_* - \log Ï_{3^{\prime\prime}}$ relation.
14 pages, 8 figures, Accepted 2019 May 22. Received 2019 May 18; in original form 2019 January 6