Tidally induced velocity gradients in the Milky Way dwarf spheroidal satellites

TL;DR

This study investigates how the Milky Way's tidal forces induce velocity gradients in its dwarf spheroidal satellites, revealing a correlation between orbital phase and internal kinematic signatures through observational data and simulations.

Contribution

It demonstrates that tidal interactions cause measurable velocity gradients in dwarf spheroidals, with gradients varying systematically with orbital position, supported by Gaia data and TNG50 simulations.

Findings

Velocity gradients are detected in several MW dwarf spheroidals.

Gradients correlate with proximity to the MW and orbital phase.

Simulations support the tidal origin of observed velocity gradients.

Abstract

We present a kinematic study of six dwarf spheroidal galaxies (dSph) satellites of the Milky Way (MW), namely Carina, Draco, Fornax, Sculptor, Sextans, and Ursa Minor. We combine proper motions (PMs) from the $Gaia$ Data Release 3 (DR3) and line-of-sight velocities ($v_{\mathrm{los}}$) from the literature to derive their 3D internal kinematics and to study the presence of internal velocity gradients. We find velocity gradients along the line-of-sight for Carina, Draco, Fornax, and Ursa Minor, at $\geq 1\sigma$ level of significance . The value of such gradients appears to be related to the orbital history of the dwarfs, indicating that the interaction with the MW is causing them. Dwarfs that are close to the MW and moving towards their orbits pericentres show, on average, larger velocity gradients. On the other hand, dwarfs that have recently left their orbits pericentres show no significant gradients. Lastly, dwarfs located at large Galactocentric distances show gradients with an intermediate intensity. Our results would indicate that the torque caused by the strong tidal forces exerted by the MW induces a strong velocity gradient when the dwarfs approach their orbits pericentres. During the pericentre passage, the rapid change in the forces direction would disrupt such gradient, which may steadily recover as the galaxies recede. We assess our findings by analysing dwarfs satellites from the TNG50 simulation. We find a significant increase in the intensity of the detected gradients as the satellites approach their pericentre, followed by a sharp drop as they abandon it, supporting our results for the dSphs of the MW.