Updating the 56Ni Problem in Core-collapse Supernova Explosion

Abstract

Details of the core-collapse supernova (CCSN) explosion mechanism still need to be fully understood. There is an increasing number of successful examples of reproducing explosions in multidimensional hydrodynamic simulations, but subsequent studies pointed out that the growth rates of the explosion energy Eexpl of these simulations are insufficient to produce enough 56Ni to match observations. This issue is known as the `56Ni problem' in CCSNe. Recently, however, some studies have suggested that this 56Ni problem is derived from the simplicity of the explosion model. In response, we investigate the effect of the explosion energy growth rate Eexpl on the behavior of nucleosynthesis in CCSNe in a more realistic model. We employ the 1D Lagrangian hydrodynamic code, in which we take neutrino heating and cooling terms into account with the light-bulb approximation. We reiterate that, consistent with previous rebuttal studies, there is the 56Ni problem: Although 56Ni is synthesized to almost the same mass coordinate independent of Eexpl, some of the innermost material in the low-Eexpl model failed to escape, leading to a shift in the innermost mass coordinate of the ejecta to the outer positions. Comparing our results with observations, we find that while modern slow explosions can, in principle, reproduce observations of standard Type II SNe, this is not possible with stripped-envelope SNe. Our finding places a strong constraint on the explosion mechanism. There are significant differences in the progenitor structures and the explosion mechanism between Type II and stripped-envelope SNe.