Jon Urrestilla scite author profile

We perform a multiparameter likelihood analysis to compare measurements of the cosmic microwave background (CMB) power spectra with predictions from models involving cosmic strings. Adding strings to the standard case of a primordial spectrum with power-law tilt ns, we find a 2sigma detection of strings: f10=0.11+/-0.05, where f10 is the fractional contribution made by strings in the temperature power spectrum (at l=10). CMB data give moderate preference to the model ns=1 with cosmic strings over the standard zero-strings model with variable tilt. When additional non-CMB data are incorporated, the two models become on a par. With variable ns and these extra data, we find that f10<0.11, which corresponds to Gmicro<0.7x10(-6) (where micro is the string tension and G is the gravitational constant).

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CMB polarization power spectra contributions from a network of cosmic strings

Bevis

et al. 2007

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We present the first calculation of the possible (local) cosmic string contribution to the cosmic microwave background polarization spectra from simulations of a string network (rather than a stochastic collection of unconnected string segments). We use field theory simulations of the Abelian Higgs model to represent local U(1) strings, including their radiative decay and microphysics. Relative to previous estimates, our calculations show a shift in power to larger angular scales, making the chance of a future cosmic string detection from the b-mode polarization slightly greater. We explore a future ground-based polarization detector, taking the Cℓover project as our example. In the null hypothesis (that cosmic strings make a zero contribution) we find that Cℓover should limit the string tension µ to Gµ < 0.12 × 10 −6 (where G is the gravitational constant), above which it is likely that a detection would be possible.

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CMB power spectrum contribution from cosmic strings using field-evolution simulations of the Abelian Higgs model

et al. 2007

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We present the first field-theoretic calculations of the contribution made by cosmic strings to the temperature power spectrum of the cosmic microwave background (CMB). Unlike previous work, in which strings were modeled as idealized one-dimensional objects, we evolve the simplest example of an underlying field theory containing local U(1) strings, the Abelian Higgs model. Limitations imposed by finite computational volumes are overcome using the scaling property of string networks and a further extrapolation related to the lessening of the string width in comoving coordinates. The strings and their decay products, which are automatically included in the field theory approach, source metric perturbations via their energy-momentum tensor, the unequal-time correlation functions of which are used as input into the CMB calculation phase. These calculations involve the use of a modified version of CMBEASY, with results provided over the full range of relevant scales. We find that the string tension $mu$ required to normalize to the WMAP 3-year data at multipole $ell = 10$ is $Gmu = [2.04pm0.06 extrm{(stat.)}pm0.12 extrm{(sys.)}] imes 10^{-6}$, where we have quoted statistical and systematic errors separately, and $G$ is Newton's constant. This is a factor 2-3 higher than values in current circulation

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Jon Urrestilla

Fitting Cosmic Microwave Background Data with Cosmic Strings and Inflation

CMB polarization power spectra contributions from a network of cosmic strings

CMB power spectrum contribution from cosmic strings using field-evolution simulations of the Abelian Higgs model

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