Physical Review Research (Feb 2022)

High-precision search for dark photon dark matter with the Parkes Pulsar Timing Array

  • Xiao Xue,
  • Zi-Qing Xia,
  • Xingjiang Zhu,
  • Yue Zhao,
  • Jing Shu,
  • Qiang Yuan,
  • N. D. Ramesh Bhat,
  • Andrew D. Cameron,
  • Shi Dai,
  • Yi Feng,
  • Boris Goncharov,
  • George Hobbs,
  • Eric Howard,
  • Richard N. Manchester,
  • Aditya Parthasarathy,
  • Daniel J. Reardon,
  • Christopher J. Russell,
  • Ryan M. Shannon,
  • Renée Spiewak,
  • Nithyanandan Thyagarajan,
  • Jingbo Wang,
  • Lei Zhang,
  • Songbo Zhang

DOI
https://doi.org/10.1103/PhysRevResearch.4.L012022
Journal volume & issue
Vol. 4, no. 1
p. L012022

Abstract

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The nature of dark matter remains obscure in spite of decades of experimental efforts. The mass of dark matter candidates can span a wide range, and its coupling with the Standard Model sector remains uncertain. All these unknowns make the detection of dark matter extremely challenging. Ultralight dark matter, with m∼10^{−22} eV, is proposed to reconcile the disagreements between observations and predictions from simulations of small-scale structures in the cold dark matter paradigm while remaining consistent with other observations. Because of its large de Broglie wavelength and large local occupation number within galaxies, ultralight dark matter behaves like a coherently oscillating background field with an oscillating frequency dependent on its mass. If the dark matter particle is a spin-1 dark photon, such as the U(1)_{B} or U(1)_{B−L} gauge boson, it can induce an external oscillating force and lead to displacements of test masses. Such an effect would be observable in the form of periodic variations in the arrival times of radio pulses from highly stable millisecond pulsars. In this study, we search for evidence of ultralight dark photon dark matter (DPDM) using 14-year high-precision observations of 26 pulsars collected with the Parkes Pulsar Timing Array. While no statistically significant signal is found, we place constraints on coupling constants for the U(1)_{B} and U(1)_{B−L} DPDM. Compared with other experiments, the limits on the dimensionless coupling constant ε achieved in our study are improved by up to two orders of magnitude when the dark photon mass is smaller than 3×10^{−22} eV (10^{−22} eV) for the U(1)_{B} (U(1)_{B−L}) scenario.