On the Connection Between Spiral Arm Pitch Angle and Galaxy Properties

Abstract: We measure the pitch angle ($\varphi$) of spiral arms in a sample of 79 galaxies to perform a systematic study of the dependence of $\varphi$ on galaxy morphology, mass, and kinematics to investigate the physical origin of spiral arms. We find that $\varphi$ decreases (arms are more tightly wound), albeit with significant scatter, in galaxies with earlier Hubble type, more prominent bulges, higher concentration, and larger total galaxy stellar mass ($M_^{\rm gal}$). For a given concentration, galaxies with larger stellar masses tend to have tighter spiral arms, and vice versa. We also find that $\varphi$ obeys a tight inverse correlation with central stellar velocity dispersion for $\sigma_c$$\gtrsim$$100$ km s$^{-1}$, whereas $\varphi$ remains approximately constant for $\sigma_c\lesssim100$ km s$^{-1}$. We demonstrate that the $\varphi$-$\sigma_c$ and $\varphi$-$M_^{\rm gal}$ relations are projections of a more fundamental three-dimensional $\varphi-\sigma_c-M_^{\rm gal}$ relation, such that pitch angle is determined by $\sigma_c$ for massive galaxies but by $M_^{\rm gal}$ for less massive galaxies. Contrary to previous studies, we find that $\varphi$ correlates only loosely with the galaxy's shear rate. For a given shear rate, spirals generated from $N$-body simulations exhibit much higher $\varphi$ than observed, suggesting that galactic disks are dynamically cooler (Toomre's $Q \approx 1.2$). Instead, the measured pitch angles show a much stronger relation with morphology of the rotation curve of the central region, such that galaxies with centrally peaked rotation curves have tight arms, while those with slow-rising rotation curves have looser arms. These behaviors are qualitatively consistent with predictions of density wave theory.