A Novel View on the Inner Crusts of Neo-Neutron Stars: exotic light nuclei, diffusional and thermodynamical stability
Abstract
Based on an extended nuclear statistical equilibrium model, we investigate the properties of non-accreted crusts of young and warm neo-neutron stars, i.e., of finite-temperature inhomogeneous dense matter in beta equilibrium. We present two novel results and one known, but frequently ignored property of such matter. The first new feature is the appearance, in the deep inner crust, of an extensive and almost pure $^{14}$He layer that extends up to the density of the transition to homogeneous matter. This layer may challenge the idea of nuclear pasta phases, significantly impact the transport properties and the crust crystallization process. Second, we raise the question of the (in)stability of the inner crust with respect to diffusion of ions (buoyancy) and demonstrate that our crust is stable, in contrast with the predictions of some other models. Finally, we show that subsaturated stellar matter is thermodynamically stable with respect to density fluctuations, which rules out a first-order phase transition between inhomogeneous and homogeneous phases.