Analytical scaling solutions for the evolution of cosmic domain walls in a parameter-free velocity-dependent one-scale model

Abstract

We derive an analytical approximation for the linear scaling evolution of the characteristic length L and the root-mean-squared velocity σv of standard frictionless domain wall networks in Friedmann-Lema\itre-Robertson-Walker universes with a power law evolution of the scale factor a with the cosmic time t (a tλ). This approximation, obtained using a recently proposed parameter-free velocity-dependent one-scale model for domain walls, reproduces well the model predictions for λ close to unity, becoming exact in the λ 1- limit. We use this approximation, in combination with the exact results found for λ=0, to obtain a fit to the model predictions valid for λ ∈ [0, 1[ with a maximum error of the order of 1 \%. This fit is also in good agreement with the results of field theory numerical simulations, specially for λ ∈ [0.9, 1[. Finally, we explicitly show that the phenomenological energy-loss parameter of the original velocity-dependent one-scale model for domain walls vanishes in the λ 1- limit and discuss the implications of this result.