The Imprint of Clump Formation at High Redshift. II. The Chemistry of the Bulge
Fisher, Deanne B.; Nidever, David L.; Valenti, Elena; Quinn, Thomas R.; Zoccali, Manuela; Debattista, Victor P.; Amarante, João A. S.; Gonzalez, Oscar A.; Beraldo e Silva, Leandro; Liddicott, David J.; Lazar, Ilin; Khachaturyants, Tigran; Du, Min; Kassin, Susan
United Kingdom, United States, Spain, Chile, Germany, Australia, China
Abstract
In Paper I, we showed that clumps in high-redshift galaxies, having a high star formation rate density (ΣSFR), produce disks with two tracks in the [Fe/H]-[α/Fe] chemical space, similar to that of the Milky Way's (MW's) thin+thick disks. Here we investigate the effect of clumps on the bulge's chemistry. The chemistry of the MW's bulge is comprised of a single track with two density peaks separated by a trough. We show that the bulge chemistry of an N-body + smoothed particle hydrodynamics clumpy simulation also has a single track. Star formation within the bulge is itself in the high-ΣSFR clumpy mode, which ensures that the bulge's chemical track follows that of the thick disk at low [Fe/H] and then extends to high [Fe/H], where it peaks. The peak at low metallicity instead is comprised of a mixture of in situ stars and stars accreted via clumps. As a result, the trough between the peaks occurs at the end of the thick disk track. We find that the high-metallicity peak dominates near the mid-plane and declines in relative importance with height, as in the MW. The bulge is already rapidly rotating by the end of the clump epoch, with higher rotation at low [α/Fe]. Thus clumpy star formation is able to simultaneously explain the chemodynamic trends of the MW's bulge, thin+thick disks, and the splash.