Probing the nature of dark matter via gravitational waves lensed by small dark matter halos

Abstract

Dark matter (DM) occupies the majority of matter content in the universe and is probably cold (CDM). However, modifications to the standard CDM model may be required by the small-scale observations, and DM may be self-interacting (SIDM) or warm (WDM). Here we show that the diffractive lensing of gravitational waves (GWs) from binary black hole mergers by small halos ($\ensuremath{\sim}{10}^{3}--{10}^{6}\text{ }\text{ }{M}_{\ensuremath{\bigodot}}$; minihalos) may serve as a clean probe to the nature of DM, free from the contamination of baryonic processes in the DM studies based on dwarf/satellite galaxies. The expected lensed GW signals and event rates resulting from CDM, WDM, and SIDM models are significantly different from each other, because of the differences in halo density profiles and abundances predicted by these models. We estimate the detection rates of such lensed GW events for a number of current and future GW detectors, such as the Laser Interferometer Gravitational Observatories (LIGO), the Einstein Telescope (ET), the Cosmic Explorer (CE), Gravitational-wave Lunar Observatory for Cosmology (GLOC), the Deci-Hertz Interferometer Gravitational Wave Observatory (DECIGO), and the Big Bang Observer (BBO). We find that GLOC may detect one such event per year assuming the CDM model, DECIGO (BBO) may detect more than several (hundreds of) such events per year, by assuming the CDM, WDM (with mass $>30\text{ }\text{ }\mathrm{keV}$) or SIDM model, suggesting that the DM nature may be strongly constrained by DECIGO and BBO via the detection of diffractive lensed GW events by minihalos. Other GW detectors are unlikely to detect a significant number of such events within a limited observational time period. However, if the inner slope of the minihalo density profile is sufficiently steeper than the Navarro-Frenk-White profile, e.g., the pseudo-Jaffe profile, one may be able to detect one to more than 100 such GW events by ET and CE.