Constraining ultralight vector dark matter with the Parkes Pulsar Timing Array second data release

TL;DR

This study searches for ultralight vector dark matter using pulsar timing data, setting upper limits on its local density and extending constraints comparable to scalar dark matter searches.

Contribution

First to constrain ultralight vector dark matter using pulsar timing array data, providing new limits on its density and properties.

Findings

No significant detection of vector dark matter signals.

Placed 95% upper limits on local dark matter density.

Constraints are comparable to scalar dark matter limits.

Abstract

Composed of ultralight bosons, fuzzy dark matter provides an intriguing solution to challenges that the standard cold dark matter model encounters on sub-galactic scales. The ultralight dark matter with mass $m\sim10^{-23} \rm{eV}$ will induce a periodic oscillation in gravitational potentials with a frequency in the nanohertz band, leading to observable effects in the arrival times of radio pulses from pulsars. Unlike scalar dark matter, pulsar timing signals induced by the vector dark matter are dependent on the oscillation direction of the vector fields. In this work, we search for ultralight vector dark matter in the mass range of $[2\times 10^{-24}, 2\times 10^{-22}]{\rm{eV}}$ through its gravitational effect in the Parkes Pulsar Timing Array (PPTA) second data release. Since no statistically significant detection is made, we place $95\%$ upper limits on the local dark matter density as $\rho_{\rm{\tiny{VF}}} \lesssim 5{\rm{GeV/cm^{3}}}$ for $m\lesssim 10^{-23}{\rm{eV}}$. As no preferred direction is found for the vector dark matter, these constraints are comparable to those given by the scalar dark matter search with an earlier 12-year data set of PPTA.