Modeling biases from constant stellar mass-to-light ratio assumption in galaxy dynamics and strong lensing
Abstract
A constant stellar mass-to-light ratio M/L has been widely-used in studies of galaxy dynamics and strong lensing, which aim at disentangling the mass distributions of dark matter and baryons. However, systematic biases arising from constant M/L assumption have not been fully quantified. In this work, we take massive early-type galaxies from the TNG100 simulation to investigate possible systematic biases in the inferences due to a constant M/L assumption. We construct two-component matter density models, where one component describes the dark matter, the other for the stars, which is made to follow the light profile by assuming a constant M/L. We fit the two-component model directly to the total matter density distributions of simulated galaxies to eliminate systematics coming from other model assumptions. We find that galaxies generally have more centrally-concentrated stellar mass profile than their light distribution. Given the light profiles adopted (i.e., single- and double-S\'ersic profiles), the assumption of a constant M/L would artificially break the model degeneracy between baryons and dark matter for non-constant M/L systems. For such systems, without knowing the true M/L but assuming a constant ratio, the two-component modeling procedure tend to generally overestimate M/L by 30\%-50\%, and underestimate the central dark matter fraction f DM by 20\% on average.
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