Cosmic Strings as Dynamical Dark Energy: Novel Constraints

Abstract

Cosmic strings, topological defects predicted by high-energy theories, may contribute to the late-time expansion of the Universe, effectively mimicking dynamical dark energy. We investigate four phenomenological extensions of the model involving a residual string network: (i) a non-relativistic component with positive energy density (Model~1), (ii) a velocity-dependent extension (Model~2), (iii) a non-relativistic string network with energy density allowed to take both positive and negative values (Model~3), and (iv) a general scenario with free energy and velocity parameters (Model~4). These models are constrained using Planck CMB data, SDSS or DESI baryon acoustic oscillations, and Type Ia supernovae observations. Models~1 and~2 yield strong upper bounds on the string density, for example, s < 0.00901 at 95\% CL from the CMB+DESI+DESY5 combination for Model~2, and mildly shift the inferred value of H0 upward, though they are not favored by Bayesian evidence. For the same combination, the bulk velocity is bound as vs < 0.569. Models~3 and~4 exhibit a consistent preference for slightly negative values of s, with CMB-only data yielding s = -0.038+0.029-0.022 and vs< 0.574 in Model~4, and a best-fit improvement of 2 = -6.07. However, these improvements are not sufficient to overcome the Occam penalty, and the Bayesian evidence continues to favor . These findings demonstrate the power of current data to constrain exotic energy components and encourage further exploration of string-inspired extensions to , particularly those involving negative-tension networks.