Probing Stochastic Ultralight Dark Matter with Space-based Gravitational-Wave Interferometers

Ultralight particles are theoretically well-motivated dark matter candidates. In the vicinity of the solar system, these ultralight particles are described as a superposition of plane waves, resulting in a stochastic field with amplitude fluctuations on scales determined by the velocity dispersion of dark matter. In this work, we systematically investigate the sensitivity of space-based gravitational-wave interferometers to the stochastic ultralight dark matter field within the frequentist framework. We derive the projected sensitivity of a single detector using the time-delay interferometry and find that the stochastic effect will only diminish the performance of the detector marginally, unlike searches in other contexts where significant reductions are found. Furthermore, we explore the sensitivity of detector network in two typical configurations. We find that the well-separated configuration, where the distance between two detectors exceeds the coherence length of dark matter, is the optimal choice for ultralight dark matter detection due to a less chance of missing signal. This contrasts with the detection of stochastic gravitational-wave background, where the co-located and co-aligned configuration is preferred. Our results may provide useful insights for potential joint observations involving gravitational-wave detectors like LISA, Taiji and TianQin.