# Search for ultralight scalar dark matter with NANOGrav pulsar timing   arrays

**Authors:** Ryo Kato, Jiro Soda

arXiv: 1904.09143 · 2020-09-30

## TL;DR

This study searches for ultralight scalar dark matter using pulsar timing data, setting new upper limits on its amplitude and energy density, and finds that observed signals may be explained by solar system effects.

## Contribution

It provides the first 11-year NANOGrav data analysis setting upper limits on ultralight scalar dark matter, improving constraints over previous studies and analyzing potential solar system effects.

## Key findings

- Set 95% confidence upper limits on scalar dark matter amplitude.
- Improved constraints compared to previous Bayesian limits.
- Identified solar system ephemeris effects as a possible signal source.

## Abstract

An ultralight scalar field is a candidate for the dark matter. The ultralight scalar dark matter with mass around $10^{-23}\,{\rm eV}$ induces oscillations of the pulse arrival time in the sensitive frequency range of the pulsar timing arrays. We search for the ultralight scalar dark matter using the North American Nanohertz Observatory for Gravitational Waves 11-year Data Set. We give the 95% confidence upper limit for the signal induced by the ultralight scalar dark matter. In comparison with the published Bayesian upper limits on the amplitude of the ultralight scalar dark matter obtained by Bayesian analysis using the Parkes Pulsar Timing Array 12-year data set (Porayko et al. 2018), we find three times stronger upper limit in the frequency range from $10^{-8.34}$ to $10^{-8.19}\,{ \rm Hz}$ which corresponds to the mass range from $9.45\times10^{-24}$ to $1.34\times10^{-23}\,{\rm eV}$. In terms of the energy density of the dark matter, we find that the energy density near the Earth is less than $7\,{\rm GeV/cm^3}$ in the range from $10^{-8.55}$ to $10^{-8.01}\,{ \rm Hz}$ (from $5.83\times10^{-24}$ to $2.02\times10^{-23}\,{\rm eV}$). The strongest upper limit on the the energy density is given by $2\,{\rm GeV/cm^3}$ at a frequency $10^{-8.28}\,{ \rm Hz}$ (corresponding to a mass $1.09\times10^{-23}\,{\rm eV}$). We find that the signal of the ultralight scalar dark matter can be explained by the solar system ephemeris effect. Also, we reveal that the model of the solar system ephemeris effect prefers parameters which are contrary to the expectation that noise will be reduced on all pulsars.

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1904.09143/full.md

## References

59 references — full list in the complete paper: https://tomesphere.com/paper/1904.09143/full.md

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Source: https://tomesphere.com/paper/1904.09143