The stochastic gravitational wave background from cosmic superstrings

Abstract

We study the stochastic gravitational wave background sourced by a network of cosmic superstrings and demonstrate that incorporating higher-mass string species, beyond the fundamental string, is crucial for accurately modelling the resulting gravitational wave spectrum across frequencies ranging from nanohertz to kilohertz. Using the multi-tension velocity-dependent one-scale model to evolve the cosmic superstring network, we perform several fits to the NANOGrav 15-year dataset and obtain expectation values for the fundamental string tension, string coupling and effective size of compact extra dimensions. We find that the cosmic superstring best-fits are comparable in likelihood to Supermassive Black Hole models, thought by many to be the leading candidate explanation of the signal. The implications of the best-fit spectra are discussed within the context of future gravitational wave experiments. We obtain expectation values for the fundamental string tension of 10(Gμ1)=-11.4+0.3-0.2(-11.5+0.3-0.2) for gravitational waves originating from large cuspy (kinky) cosmic superstring loops and 10(Gμ1)=-9.7+0.7-0.7(-9.9+1.0-0.5) for small cuspy (kinky) loops. We also place 2σ upper bounds on the string coupling, finding gs<0.7 in all cases, and comment on the implication of our results for the effective size of the compact extra dimensions.

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