Cosmological attractors to general relativity and spontaneous scalarization with disformal coupling

Abstract

The canonical scalar-tensor theory model which exhibits spontaneous scalarization in the strong-gravity regime of neutron stars has long been known to predict a cosmological evolution for the scalar field which generically results in severe violations of present-day Solar System constraints on deviations from general relativity. We study if this tension can be alleviated by generalizing this model to include a disformal coupling between the scalar field and matter, where the Jordan frame metric gμ is related to the Einstein frame one gμ by gμ=A()2 (gμ+\, ∂μ \, ∂). We find that this broader theory admits a late-time attractor mechanism towards general relativity. However, the existence of this attractor requires a value of disformal scale of the order H0-2, where H0 is the Hubble parameter of today, which is much larger than the scale relevant for spontaneous scalarization of neutron stars Rs2 with Rs ( 10-22 H0-1) being the typical radius of these stars. The large values of necessary for the attractor mechanism (i) suppress spontaneous scalarization altogether inside neutron stars and (ii) induce ghost instabilities on scalar field fluctuations, thus preventing a resolution of the tension. We argue that the problem arises because our disformal coupling involves a dimensionful parameter.