Microlensing analysis of 14.5-year light curves in SDSS J1004+4112: Quasar accretion disk size and intracluster stellar mass fraction

Context. The gravitational lens system SDSS J1004+4112 was the first known example of a quasar lensed by a galaxy cluster. The interest in this system has been renewed following the publication of r-band light curves spanning 14.5 years and the determination of the time delays between the four brigh...

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Bibliographic Details
Published in:arXiv.org 2024-10
Main Authors: és-Toribio, R, Muñoz, J A, Fian, C, Jiménez-Vicente, J, Mediavilla, E
Format: Article
Language:English
Subjects:
Accretion disks
Galactic clusters
Gravitational lenses
Histograms
Light
Light curve
Microlenses
Quasars
Stellar mass
Stellar mass accretion
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Summary:Context. The gravitational lens system SDSS J1004+4112 was the first known example of a quasar lensed by a galaxy cluster. The interest in this system has been renewed following the publication of r-band light curves spanning 14.5 years and the determination of the time delays between the four brightest quasar images. Aims. We constrained the quasar accretion disk size and the fraction of the lens mass in stars using the signature of microlensing in the quasar image light curves. Methods. We built the six possible histograms of microlensing magnitude differences between the four quasar images and compared them with simulated model histograms, using a \(\chi^2\) test to infer the model parameters. Results. We infer a quasar disk half-light radius of \(R_{1/2}=(0.70\pm0.04)\, R_E=(6.4\pm0.4) \sqrt{M/0.3M_{\odot}}\) light-days at 2407Å in the rest frame and stellar mass fractions at the quasar image positions of \(\alpha_A>0.059\), \(\alpha_B=0.056^{+0.021}_{-0.027}\), \(\alpha_C=0.030^{+0.031}_{-0.021}\), and \(\alpha_D=0.072^{+0.034}_{-0.016}\). Conclusions. The inferred disk size is broadly compatible with most previous estimates, and the stellar mass fractions are within the expected ranges for galaxy clusters. In the region where image C lies, the stellar mass fraction is compatible with a stellar contribution from the brightest cluster galaxy, galaxy cluster members, and intracluster light, but the values at images B, D, and especially A are slightly larger, possibly suggesting the presence of extra stellar components.
ISSN:2331-8422