Effects of Galaxy Cluster Structure on Lensed Transients (2501.02096v1)

Abstract: Strong gravitational lenses come in many forms, but are typically divided into two populations: galaxies, and groups and clusters of galaxies. When calculating the properties of the images we expect to see from these lenses, it is typically assumed that each lens is roughly a singular isothermal sphere. In reality, the largest objects in the Universe (i.e. galaxy clusters) are highly irregular and composed of many components due to a history of (or active) hierarchical mergers. In this work, we analyze the discrepancies in the observables of strongly lensed transients in both scenarios, namely relative magnifications, time delays, and image multiplicities. Focusing on gravitational waves, we compare the detection rates between the single spherical dark matter halo models found in the literature, and publicly available state-of-the-art cluster lens models. We find there to be approximately an order of magnitude fewer detection of strongly lensed transients in the realistic model case, likely caused by their loss of overall strong lensing optical depth. We also report detection rates in the weak lensing or single-image regime. Additionally, we find a systemic shift towards lower time delays between the brightest image pairs in the cases of the realistic models, as well as higher fractions of positive versus negative parity images, as seen elsewhere in the literature. This significant deviation in the joint relative magnification factor-time delay distribution will hinder the feasibility of the reconstruction of lenses through time domain transients alone, but can still provide a lower limit on the lens mass.