Impacts of hydrogen envelope on supernova fallback and the resulting compact remnant masses

Abstract

Fallback in core-collapse supernovae plays a central role in setting compact-remnant masses and may produce late-time emission. In hydrogen rich progenitors, the reverse shock arising at the hydrogen-helium interface has the potential to dramatically enhance fallback, yet its overall impact across a broad explosion-energy range has not been systematically quantified. Using one-dimensional hydrodynamic simulations for metal-poor progenitors with M ZAMS=18-28\,M and models with and without hydrogen envelopes, we explore fallback over explosion energies of 1048-1052\, erg. We find a robust and universal mass-transition behaviour: when the explosion energy reaches only 2-3 times the binding energy of the hydrogen envelope, the reverse shock returns to the centre and sharply increases the remnant mass by 2\,M. Above this threshold, the reverse shock escapes and hydrogen-rich and stripped-envelope progenitors yield nearly identical remnant masses. By normalizing the results with the envelope binding energy, we show that all progenitor models converge to a common fallback relation. We further provide a simple analytic prescription that connects explosion energy, hydrogen-envelope binding energy, and final compact-remnant mass. This relation provides an important link between progenitor properties and compact-remnant masses, and is useful for population-synthesis and galactic chemical-evolution studies.

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