Population III Supernovae as a dust factory I --- molecule formation and mixing/fallback in ejecta
Abstract
Recent observations have revealed the spectral feature of carbonaceous grains even in a very distant galaxy. We develop a state-of-the-art dust synthesis code by self-consistently solving molecule and dust formation in supernova (SN) ejecta that contain various elements in different layers. With a progenitor mass 25 Msun and explosion energy 1052 erg, we run the following four test calculations to investigate the impact of input physics. (i) With molecule formation solved, our SN model produces 8.45x10-2 Msun carbonaceous grains. (ii) If all available C and Si were initially depleted into CO and SiO molecules, respectively, the C grain mass could be underestimated by ~40%. In these two models producing 0.07 Msun 56Ni without mixing fallback, a large amount of silicates (0.260 Msun) created in O-rich layers are also ejected and likely to hide the spectral feature of carbonaceous grains. We then consider mixing-fallback that can reproduce the observed elemental abundance ratios of C-normal and C-enhanced extremely metal-poor stars in the Milky Way. (iii) In the former, the mass ratio of carbonaceous to silicate grains is still small (~0.3). However, (iv) in the latter (known as a ``faint SN'), while the C grain mass is unchanged (6.78x10-2 Msun), the silicate mass is reduced (9.98x10-3 Msun). Therefore, we conclude that faint SNe can be a significant carbonaceous dust factory in the early Universe.
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