Tracing the kinematic perturbations of the Milky Way spiral arms with APOGEE DR17 and Gaia DR3

Abstract

Aims. We constrain the dynamical perturbations of the spiral arms in the Milky Way disk, based on the non-axisymmetric streaming motions of RGB stars revealed by APOGEE and Gaia. Methods. We develop a revised steady-state radial-velocity response model that incorporates both the \(VR,\) and the dynamically important \(VR,\) components for a two-armed logarithmic spiral potential. The model is validated using orbit integrations with AGAMA and Bayesian parameter recovery with dynesty, and is applied to the smoothed two-dimensional radial-velocity field of RGB stars while accounting for Lindblad and corotation resonances. Results. The revised model reproduces the phase and amplitude of the mock radial-velocity field to the \(2\%\) level, substantially improving upon earlier \(VR,\)-only formulations. Applied to the observational data, it yields a robust pitch angle of \(p 10\) and a local surface density contrast of \(ξ 5\)--\(18\%\) at the solar radius. The radial scale length is less well-constrained (\(hR,1 40\)--\(50\,kpc\)) due to intrinsic parameter covariance. Resonance effects strongly shape the velocity field, thus affecting the fitting: the radial velocity becomes extremely large near the Lindblad resonances, whereas it vanishes close to the corotation resonance. Conclusions. Our results demonstrate that including both the \(VR,\) and \(VR,\) terms is essential for a physically consistent interpretation of stellar streaming motions induced by a spiral potential. The observed kinematics constrain the spiral pattern speed to \(Ωp ≈ 10\)--\(20\,km\,s-1kpc-1\).