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Physics 133: Extragalactic Astronomy and Cosmology

Discover how strong lensing can unveil accurate mass maps of celestial objects, enabling cosmography and testing of gravitational theories. This lecture dives into the practical steps of measuring time delays, solving astrometry problems, and overcoming mass-sheet degeneracy in cosmography using gravitational lensing. Learn about the COSMOGRAIL project monitoring time delays of lensed quasars and breaking the slope-H0 degeneracy. Enhance your understanding of lens models and the significance of time delays in comparing with other probes like WMAP7owCDM. Unveil the applications of lensing in measuring the mass of galaxies, clusters, and planets, testing cosmological models, probing gravity, and studying dark matter properties. Journeys through the wonders of lensing in unraveling the mysteries of the universe!

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Physics 133: Extragalactic Astronomy and Cosmology

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  1. Physics 133: Extragalactic Astronomy and Cosmology Lecture 13; February 26 2014

  2. Previously • Mass concentrations distort the images of objects in on the sky in a way similar to that of optical images. • Strong and weak lensing provide very accurate mass maps of objects (in projection) • Gravitational field “slows down” light. Strong lensing can be formulated in terms of Fermat’s principle

  3. Outline: • Cool things you can do with lensing (applications): • Cosmography (Hubble Constant) • Useful link: • Saas Fee Lectures on gravitational lensing • http://www.astro.uni-bonn.de/~peter/SaasFee.html • (Particularly the first one by Peter Schneider)

  4. Cosmography with time-delays

  5. Time delay distance in practice • Steps: • Measure the time-delay between two images • Measure and model the potential • Infer the time-delay distance • Convert it into cosmlogical parameters Riess et al. 2011

  6. Cosmography with strong lenses:the 4 problems solved • Time delay – 2-3 % • Tenacious monitoring (e.g. Fassnacht et al. 2002); COSMOGRAIL (Meylan/Courbin) • Astrometry – 10-20 mas • Hubble/VLA/(Adaptive Optics?) • Lens potential (2-3%) • Stellar kinematics/Extended sources (Treu & Koopmans 2002; Suyu et al. 2009) • Structure along the line of sight (2-3%) and the mass-sheet degeneracy, • Galaxy counts and numerical simulations (Suyu et al. 2009) • Stellar kinematics (Koopmans et al. 2003)

  7. Gravitational Lens Time Delays

  8. COSMOGRAIL: the COSmologicalMOnitoring of GRAvItational Lenses • time delays of lensed quasars from optical monitoring • expect to have delays with a few percent error for ~20 lenses

  9. The slope-H0 degeneracy • Uncertainty of the mass density profile of the main lens is the single largest source of uncertainty. • If mass density profile is a power law ρ~r-γ’then H0(γ’)~H0(2)(γ’-1) (Wucknitz 2002) • Can be broken using lensing (Suyu et al. 2010) and stellar kinematic data (Treu & Koopmans 2002) • We need to know the slope of the mass density profile to break this degeneracy! • The degeneracy can be broken using multiple time delays, extended rings, and external information such as stellar kinematics

  10. Lens Model Observed Image

  11. light distributionof extended source mass distributionof lens Lens Model

  12. light distributionof extended source mass distributionof lens light of lensed AGN Lens Model

  13. light distributionof extended source mass distributionof lens light of lens (Sersic) light of lensed AGN Lens Model

  14. light distributionof extended source mass distributionof lens light of lens (Sersic) light of lensed AGN Lens Model + time delays

  15. Lens Model

  16. Time delays vs other probes WMAP7owCDM prior [Suyu et al. 2012] • contour orientations are different: complementarity b/w probes • contour sizes are similar: lensing is a competitive probe

  17. Summary. Applications of lensing • Measure mass of galaxies, clusters planets. • Test the cosmological model by measuring substructure • Cosmography • Test gravity • Properties of dark matter

  18. The End See you on monday!

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