Abstract
A power-law density model, i.e., $\rho(r) \propto r^{-\gamma'}$ has been commonly employed in strong gravitational lensing studies, including the so-called time-delay technique used to infer the Hubble constant $H_0$. However, since the radial scale at which strong lensing features are formed corresponds to the transition from the dominance of baryonic matter to dark matter, there is no known reason why galaxies should follow a power law in density. The assumption of a power law artificially breaks the mass-sheet degeneracy, a well-known invariance transformation in gravitational lensing which affects the product of Hubble constant and time delay and can therefore cause a bias in the determination of $H_0$ from the time-delay technique. In this paper, we use the Illustris hydrodynamical simulations to estimate the amplitude of this bias, and to understand how it is related to observational properties of galaxies. Investigating a large sample of Illustris galaxies that have velocity dispersion $\sigma_{SIE}$>160 km/s at redshifts below $z=1$, we find that the bias on $H_0$ introduced by the power-law assumption can reach 20%-50%, with a scatter of $10\%-30\%$ (rms). However, we find that by selecting galaxies with an inferred power-law model slope close to isothermal, it is possible to reduce the bias on $H_0$ to <5%, and the scatter to <10%. This could potentially be used to form less biased statistical samples for $H_0$ measurements in the upcoming large survey era.
Highlights
Strong gravitational lensing is a major tool of modern extragalactic astrophysics
Ever since its first discovery (Walsh et al 1979), it has been used as a natural telescope to magnify the distant Universe, a scale to weigh galaxies, and a ladder to measure the Hubble constant H0 – the expansion rate of the Universe (Refsdal 1964)
The observational properties of galaxy-scale strong lens systems depend mainly on the mass distribution inside and near the Einstein radius of the lens, which corresponds in general to a few half-light radii. Both dark and baryonic matter are believed to coexist in roughly similar amounts
Summary
Strong gravitational lensing is a major tool of modern extragalactic astrophysics. Ever since its first discovery (Walsh et al 1979), it has been used as a natural telescope to magnify the distant Universe, a scale to weigh galaxies, and a ladder to measure the Hubble constant H0 – the expansion rate of the Universe (Refsdal 1964). The observational properties of galaxy-scale strong lens systems (i.e. positions and flux ratios of unresolved images, brightness distribution of lensed extended components, and time-delays) depend mainly on the mass distribution inside and near the Einstein radius of the lens, which corresponds in general to a few half-light radii. Within this radius, both dark and baryonic matter are believed to coexist in roughly similar amounts.
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