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Constraining HeII Reionization Detection Uncertainties via Fast Radio Bursts

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 Added by Ayan Mitra
 Publication date 2020
  fields Physics
and research's language is English




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Context. The increased detection rate of Fast Radio Bursts (FRBs) makes it likely to get samples of sizes $mathcal{O}(10^2)$ to $mathcal{O}(10^3)$ in the near future. Because of their extragalactic origin can help us in understanding the epoch of helium reionization. Aims. We try to identify the epoch of Helium II (HeII) reionization, via the observations of early FRBs in range of $z=3$ to $4$. Methods. We build a model of FRB Dispersion Measure following the HeII reionization model, density fluctuation in large scale structure, host galaxy interstellar medium and local environment of FRB contribution. The model is fit to the ideal intergalactic medium (IGM) dispersion measure model to check the goodness of constraining the HeII reionization via FRB measurement statistics. Conclusion. We report our findings under two categories, accuracy in detection of HeII reionization via FRBs assuming no uncertainty in the redshift measurement and alternatively assuming a varied level of uncertainty in redshift measurement of the FRBs. We show that under the first case, a detection of $Nsimmathcal{O} (10^2)$ FRBs give an uncertainty of $sigma (z_{r, fit})sim0.5$ from the fit model, and a detection of $Nsimmathcal{O} (10^3)$ gives an uncertainty of $sigma (z_{r, fit})sim0.1$. While assuming a redshift uncertainty of level $5-20%$, changes the $sigma (z_{r, fit})sim0.5$ to $0.6$ for $Nsim 100$ and $sigma (z_{r, fit})sim0.1$ to $0.15$ for $N sim 1000$ case.



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77 - M. Caleb , C. Flynn , B. Stappers 2019
The discovery of fast radio bursts (FRBs) about a decade ago opened up new possibilities for probing the ionization history of the Intergalactic Medium (IGM). In this paper we study the use of FRBs for tracing the epoch of HeII reionization, using simulations of their dispersion measures. We model dispersion measure contributions from the Milky Way, the IGM (homogeneous and inhomogeneous) and a possible host galaxy as a function of redshift and star formation rate. We estimate the number of FRBs required to distinguish between a model of the Universe in which helium reionization occurred at z = 3 from a model in which it occurred at z = 6 using a 2-sample Kolmogorov-Smirnoff test. We find that if the IGM is homogeneous >1100 FRBs are needed and that an inhomogeneous model in which traversal of the FRB pulse through galaxy halos increases the number of FRBs modestly, to >1600. We also find that to distinguish between a reionization that occurred at z = 3 or z = 3.5 requires ~5700 FRBs in the range 3 < z < 5.
110 - C. Nu~nez , N. Tejos , G. Pignata 2021
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109 - Ji-Ping Dai , Jun-Qing Xia 2020
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