# Cosmic Microwave Background constraints for global strings and global   monopoles

**Authors:** Asier Lopez-Eiguren, Joanes Lizarraga, Mark Hindmarsh, Jon, Urrestilla

arXiv: 1705.04154 · 2017-07-28

## TL;DR

This paper presents the first CMB power spectra derived from numerical simulations of global strings and monopoles, revealing non-trivial correlations and setting constraints on their contribution to CMB anisotropies.

## Contribution

It introduces a novel computation of CMB spectra from global topological defects using UETCs, and demonstrates their larger-than-expected amplitudes compared to large-N predictions.

## Key findings

- CMB spectra for global strings and monopoles have similar shapes to non-linear sigma model predictions.
- Amplitudes of the spectra are significantly larger than large-N calculations, especially for global strings.
- Constraints on defect contributions limit symmetry-breaking scales and impact axion and gravitational wave models.

## Abstract

We present the first CMB power spectra from numerical simulations of the global O(N) linear $\sigma$-model with N = 2,3, which have global strings and monopoles as topological defects. In order to compute the CMB power spectra we compute the unequal time correlators (UETCs) of the energy-momentum tensor, showing that they fall off at high wave number faster than naive estimates based on the geometry of the defects, indicating non-trivial (anti-)correlations between the defects and the surrounding Goldstone boson field. We obtain source functions for Einstein-Boltzmann solvers from the UETCs, using a recent method that improves the modelling at the radiation- matter transition. We show that the interpolation function that mimics the transition is similar to other defect models, but not identical, confirming the non-universality of the interpolation function. The CMB power spectra for global strings and monopoles have the same overall shape as those obtained using the non-linear $\sigma$-model approximation, which is well captured by a large-N calculation. However, the amplitudes are larger than the large-N calculation predict, and in the case of global strings much larger: a factor of 20 at the peak. Finally we compare the CMB power spectra with the latest CMB data to put limits on the allowed contribution to the temperature power spectrum at multipole $\ell$ = 10 of 1.7% for global strings and 2.4% for global monopoles. These limits correspond to symmetry-breaking scales of 2.9x1015 GeV (6.3x1014 GeV with the expected logarithmic scaling of the effective string tension between the simulation time and decoupling) and 6.4x1015 GeV respectively. The bound on global strings is a significant one for the ultra-light axion scenario with axion masses ma 10-28 eV. These upper limits indicate that gravitational wave from global topological defects will not be observable at the GW observatory LISA.

## Full text

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## Figures

27 figures with captions in the complete paper: https://tomesphere.com/paper/1705.04154/full.md

## References

57 references — full list in the complete paper: https://tomesphere.com/paper/1705.04154/full.md

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Source: https://tomesphere.com/paper/1705.04154