Upcoming searches for decaying dark matter with ULTRASAT ultraviolet maps
Sarah Libanore, Ely D. Kovetz
arXiv:2404.01500v1 Announce Type: new
Abstract: Decaying dark matter (DDM) can be tested via different astrophysical and cosmological probes. In particular, particles in the $sim$ 9.5 – 30 eV mass range that decay into monochromatic photons, would contribute to the extragalactic background light (EBL) in the ultraviolet (UV) bandwidth. In this work, we show that an intriguing improvement to the constraints on such DDM models can come from broadband UV surveys, such as GALEX or the upcoming ULTRASAT satellite. These provide diffuse light maps of the UV EBL, integrated over a wide redshift range. The cross correlation between intensity fluctuations in these maps with a reference spectroscopic galaxy survey, can be used to reconstruct the redshift evolution of the EBL intensity; in this way, it is also possible to detect signatures of contributions from DDM. We forecast the constraining power of (GALEX+ULTRASAT)$times$DESI, and we show they will be able to detect DDM with decay rate up to $mathcal{O}(10^{-26},{rm s})$. In the context of axion-like particles (ALP), our forecasts can be converted to constraints on the ALP-photon coupling; our results show this technique will test ALP with coupling $lesssimmathcal{O}(10^{-12},{rm GeV^{-1}})$, more than an order of magnitude better than current bounds in this mass range.arXiv:2404.01500v1 Announce Type: new
Abstract: Decaying dark matter (DDM) can be tested via different astrophysical and cosmological probes. In particular, particles in the $sim$ 9.5 – 30 eV mass range that decay into monochromatic photons, would contribute to the extragalactic background light (EBL) in the ultraviolet (UV) bandwidth. In this work, we show that an intriguing improvement to the constraints on such DDM models can come from broadband UV surveys, such as GALEX or the upcoming ULTRASAT satellite. These provide diffuse light maps of the UV EBL, integrated over a wide redshift range. The cross correlation between intensity fluctuations in these maps with a reference spectroscopic galaxy survey, can be used to reconstruct the redshift evolution of the EBL intensity; in this way, it is also possible to detect signatures of contributions from DDM. We forecast the constraining power of (GALEX+ULTRASAT)$times$DESI, and we show they will be able to detect DDM with decay rate up to $mathcal{O}(10^{-26},{rm s})$. In the context of axion-like particles (ALP), our forecasts can be converted to constraints on the ALP-photon coupling; our results show this technique will test ALP with coupling $lesssimmathcal{O}(10^{-12},{rm GeV^{-1}})$, more than an order of magnitude better than current bounds in this mass range.