MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY, v.496, no.4, pp.4606 - 4623
Abstract
In this work, we analyse the connection between gas availability and the position of a region with respect to the spatially resolved main-sequence (MS) relation. Following the procedure presented in Enia et al. (2020), for a sample of five face-on, grand design spiral galaxies located on the MS we obtain estimates of stellar mass and star formation rate surface densities (Sigma(*) and Sigma(SFR)) within cells of 500 pc size. Thanks to HI 21cm and (CO)-C-12(2-1) maps of comparable resolution, within the same cells we estimate the surface densities of the atomic (Sigma(HI)) and molecular (Sigma(H2)) gas and explore the correlations among all these quantities. Sigma(*), Sigma(SFR), and Sigma(H2) define a 3D relation whose projections are the spatially resolved MS, the Kennicutt-Schmidt law and the molecular gas MS. We find that Sigma(H2) steadily increases along the MS relation and is almost constant perpendicular to it. Sigma(HI) is nearly constant along theMS and increases in its upper envelope. As a result, Sigma(SFR) can be expressed as a function of Sigma(*) and Sigma(HI), following the relation log Sigma(SFR) = 0.97log Sigma(*) + 1.99log Sigma(HI) - 11.11. We show that the total gas fraction significantly increases towards the starburst regions, accompanied by a weak increase in star formation efficiency. Finally, we find that H-2/H I varies strongly with the distance from theMS, dropping dramatically in regions of intense star formation, where the UV radiation from newly formed stars dissociates the H-2 molecule, illustrating the self-regulating nature of the star formation process.