Parameter-free velocity-dependent one-scale model for domain walls

Abstract

We develop a parameter-free velocity-dependent one-scale model for the evolution of the characteristic length L and root-mean-square velocity σv of standard domain wall networks in homogeneous and isotropic cosmologies. We compare the frictionless scaling solutions predicted by our model, in the context of cosmological models having a power law evolution of the scale factor a as a function of the cosmic time t (a tλ, 0< λ < 1), with the corresponding results obtained using field theory numerical simulations. We show that they agree well (within a few \%) for root-mean-square velocities σv smaller than 0.2 \, c (λ 0.9), where c is the speed of light in vacuum, but significant discrepancies occur for larger values of σv (smaller values of λ). We identify problems with the determination of L and σv from numerical field theory simulations which might potentially be responsible for these discrepancies.