Mark G. Alford, Sophia Han, Madappa Prakash
We study the stability and maximum mass of hybrid stars, assuming a generic quark matter equation of state with a single first-order phase transition between nuclear and quark matter, and a sharp interface between the quark matter core and nuclear matter mantle in a neutron star. For standard nuclear matter equations of state, we find that the mass-radius relation contains a stable hybrid branch, connected to the nuclear matter star branch, if the energy density discontinuity at the nuclear-quark transition is less than a critical value, which is typically between 60% and 80% of the nuclear matter energy density at the transition. Extending the quark matter equation of state to higher densities by assuming it has a density-independent speed of sound, we find that, as has been noticed before, there can be a disconnected branch of hybrid stars (sometimes called "third family" of stars). For typical nuclear matter equations of state, this branch exists if the nuclear matter density at the transition is less than a critical value which is about two to four times nuclear saturation density. We calculate the maximum hybrid star mass as a function of the nuclear matter density and the parameters of the quark matter EoS, and find that, for apparently reasonable values of the quark matter parameters, hybrid stars with mass above $2\,M_\odot$ can exist.
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http://arxiv.org/abs/1302.4732
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