Effects of radial flows on the chemical evolution of the Milky Way disk

TL;DR

This paper investigates how radial gas flows influence the chemical evolution and metallicity gradients of the Milky Way disk, highlighting the importance of variable flow speeds and other factors in modeling observed data.

Contribution

It demonstrates that variable radial gas flow speeds are crucial for accurately modeling the Milky Way's metallicity gradients, challenging simpler constant-speed assumptions.

Findings

Radial inflows tend to steepen metallicity gradients.

Variable gas flow speeds are necessary to match observed gradients.

Inside-out formation and star formation thresholds can also reproduce gradients.

Abstract

The majority of chemical evolution models assume that the Galactic disk forms by means of infall of gas and divide the disk into several independent rings without exchange of matter between them. However, if gas infall is important, radial gas flows should be taken into account as a dynamical consequence of infall. The aim of this paper is to test the effect of radial gas flows on detailed chemical evolution models (one-infall and two-infall) for the Milky Way disk with different prescriptions for the infall law and star formation rate. We found, that with a gas radial inflow of constant speed the metallicity gradient tends to steepen. Taking into account a constant time scale for the infall rate along the Galaxy disk and radial flows with a constant speed, we obtained a too flat gradient, at variance with data, implying that an inside-out formation and/or a variable gas flow speed are required. To reproduce the observed gradients the gas flow should increase in modulus with the galactocentric distance, both in the one-infall and two-infall models. However, the inside-out disk formation coupled with a threshold in the gas density (only in the two-infall model) for star formation and/or a variable efficiency of star formation with galactocentric distance can also reproduce the observed gradients without radial flows. We showed that the radial flows can be the most important process in reproducing abundance gradients but only with a variable gas speed. Finally, one should consider that uncertainties in the data concerning gradients prevent us to draw firm conclusions. Future more detailed data will help to ascertain whether the radial flows are a necessary ingredient in the formation and evolution of the Galactic disk and disks in general.