Direct multi-model dark-matter search with gravitational-wave interferometers using data from the first part of the fourth LIGO-Virgo-KAGRA observing run

Abstract

Gravitational-wave detectors can probe the existence of dark matter with exquisite sensitivity. Here, we perform a search for three kinds of dark matter -- dilatons (spin-0), dark photons (spin-1) and tensor bosons (spin-2) -- using three independent methods on the first part of the most recent data from the fourth observing run of LIGO--Virgo--KAGRA. Each form of dark matter could have interacted with different standard-model particles in the instruments, causing unique differential strains on the interferometers. While we do not find any evidence for a signal, we place the most stringent upper limits to-date on each of these models. For scalars with masses between [4× 10-14,1.5× 10-13] eV that couple to photons or electrons, our constraints improve upon those from the third observing run by one order of magnitude, with the tightest limit of 10-20\,GeV-1 at a mass of 2× 10-13 eV. For vectors with masses between [7× 10-13,8.47× 10-12] eV that couple to baryons, our constraints supersede those from MICROSCOPE and E\"ot-Wash by one to two orders of magnitude, reaching a minimum of 5× 10-24 at a mass of 10-12 eV. For tensors with masses of [4× 10-14,8.47× 10-12] eV (the full mass range analyzed) that couple via a Yukawa interaction, our constraints surpass those from fifth-force experiments by four to five orders of magnitude, achieving a limit as low as 8× 10-9 at 2× 10-13 eV. Our results show that gravitational-wave interferometers have become frontiers for new physics and laboratories for direct multi-model dark-matter detection.

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