Generating ultra compact boson stars with modified scalar potentials

Abstract

The properties of selfinteracting boson stars with different scalar potentials going beyond the commonly used φ4 ansatz are studied. The scalar potential is extended to different values of the exponent n of the form V φn. Two stability mechanism for boson stars are introduced, the first being a mass term and the second one a vacuum term. We present analytic scale-invariant expressions for these two classes of equations of state. The resulting properties of the boson star configurations differ considerably from previous calculations. We find three different categories of mass-radius relation: the first category resembles the mass-radius curve of selfbound stars, the second one those of neutron stars and the third one is the well known constant radius case from the standard φ4 potential. We demonstrate that the maximal compactness can reach extremely high values going to the limit of causality Cmax = 0.354 asymptotically for n∞. The maximal compactnesses exceed previously calculated values of Cmax=0.16 for the standard φ4-theory and Cmax=0.21 for vector-like interactions and is in line with previous results for solitonic boson stars. Hence, boson stars even described by a simple modified scalar potential in the form of V φn can be ultra compact black hole mimickers where the photon ring is located outside the radius of the star.