# Luminosity-duration relation of fast radio bursts

**Authors:** Tetsuya Hashimoto, Tomotsugu Goto, Ting-Wen Wang, Seong Jin Kim,, Yi-Han Wu, and Chien-Chang Ho

arXiv: 1907.11730 · 2019-08-07

## TL;DR

This paper proposes a new method using the luminosity-duration relation of fast radio bursts (FRBs) to measure cosmological distances, potentially constraining dark energy properties beyond the reach of supernovae.

## Contribution

It introduces an empirical luminosity-duration correlation in FRBs and demonstrates its potential as a standard candle for cosmology, offering advantages over existing methods.

## Key findings

- A positive correlation between FRB luminosity and intrinsic duration was identified.
- The method can measure high-redshift distances independent of intergalactic medium uncertainties.
- Simulations show potential for constraining dark energy evolution with future FRB observations.

## Abstract

Nature of dark energy remains unknown. Especially, to constrain the time variability of the dark-energy, a new, standardisable candle that can reach more distant Universe has been awaited. Here we propose a new distance measure using fast radio bursts (FRBs), which are a new emerging population of $\sim$ ms time scale radio bursts that can reach high-$z$ in quantity. We show an empirical positive correlation between the time-integrated luminosity (L$_{\nu}$) and rest-frame intrinsic duration ($w_{\rm int,rest}$) of FRBs. The L$_{\nu}-w_{\rm int,rest}$ correlation is with a weak strength but statistically very significant, i.e., Pearson coefficient is $\sim$ 0.5 with p-value of $\sim$0.038, despite the smallness of the current sample. This correlation can be used to measure intrinsic luminosity of FRBs from the observed $w_{\rm int,rest}$. By comparing the luminosity with observed flux, we measure luminosity distances to FRBs, and thereby construct the Hubble diagram. This FRB cosmology with the L$_{\nu}-w_{\rm int,rest}$ relation has several advantages over SNe Ia, Gamma-Ray Burst (GRB), and well-known FRB dispersion measure (DM)-$z$ cosmology; (i) access to higher redshift Universe beyond the SNe Ia, (ii) high event rate that is $\sim$ 3 order of magnitude more frequent than GRBs, and (iii) it is free from the uncertainty from intergalactic electron density models, i.e., we can remove the largest uncertainty in the well-debated DM-$z$ cosmology of FRB. Our simulation suggests that the L$_{\nu}-w_{\rm int,rest}$ relation provides us with useful constraints on the time variability of the dark energy when the next generation radio telescopes start to find FRBs in quantity.

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/1907.11730/full.md

## References

43 references — full list in the complete paper: https://tomesphere.com/paper/1907.11730/full.md

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Source: https://tomesphere.com/paper/1907.11730