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Thomas Collett Institute of Astronomy, Cambridge

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1 Thomas Collett Institute of Astronomy, Cambridge
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Institute of Astronomy, Cambridge With: Matt Auger, Vasily Belokurov, Phil Marshall and others ArXiv: , ArXiv: and unpublished work

2 What is double source plane strong lensing?
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett What is double source plane strong lensing?

3 What is double source plane strong lensing?
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett What is double source plane strong lensing? A gravitational lens system with two background sources, each at a different redshift.

4 What is double source plane strong lensing?
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett What is double source plane strong lensing? A gravitational lens system with two background sources, each at a different redshift. SLACS J

5 What is double source plane strong lensing?
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett What is double source plane strong lensing? A gravitational lens system with two background sources, each at a different redshift. Lens Galaxy SLACS J

6 What is double source plane strong lensing?
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett What is double source plane strong lensing? A gravitational lens system with two background sources, each at a different redshift. Images of the intermediate source SLACS J

7 What is double source plane strong lensing?
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett What is double source plane strong lensing? A gravitational lens system with two background sources, each at a different redshift. Images of the background source SLACS J

8 Two important quantities:
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Two important quantities: The Einstein Radius: Angular diameter distances (flat universe, w constant): Image configurations depend on the underlying cosmology.

9 The observable: The Ratio of Einstein Radii.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett The observable: The Ratio of Einstein Radii.

10 The observable: The Ratio of Einstein Radii.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett The observable: The Ratio of Einstein Radii.

11 The observable: The Ratio of Einstein Radii.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett The observable: The Ratio of Einstein Radii.

12 No dependence on the Hubble constant!
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett The observable: The Ratio of Einstein Radii. No dependence on the Hubble constant!

13 Jullo et al. (2010) Results: ΩM= 0.25 ± 0.05, wDE = −0.97 ± 0.07
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Jullo et al. (2010) Results: ΩM= 0.25 ± 0.05, wDE = −0.97 ± 0.07 (Abel WMAP5 + X-ray cluster constraints) The mass is very complicated Hard to control systematics

14 Constraining Dark Energy with Double Source Plane Strong Lenses
Thomas Collett Jullo et al. (2010) Results:

15 Constraining Cosmology.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Constraining Cosmology. Preliminary models of J0946 suggest statistical uncertainty of ~1% on the ratio of Einstein Radii. Uncertainty is dominated by the lens' mass density slope Let's assume some redshifts, and a 1% uncertainty on η.

16 Constraining Cosmology.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Constraining Cosmology. zl = 0.35 zs1 = 0.6 zs2 = 1.5

17 Constraining Cosmology.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Constraining Cosmology. zl = 0.35 zs1 = 0.6 zs2 = 1.5 WMAP

18 Constraining Cosmology.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Constraining Cosmology. zl = 0.35 zs1 = 0.6 zs2 = 1.5 WMAP Combination

19 Finding more systems Piggy-back on deep, large area surveys
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Finding more systems Piggy-back on deep, large area surveys Target the most massive galaxies

20 Constraints with 6 systems.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Constraints with 6 systems. Forecast the distribution of lens and source redshifts WMAP+6 systems is ~2.5 times better than WMAP+1. WMAP+ 1 system wDE = −0.99 ± 0.27 6 systems wDE = −1.01 ± 0.11

21 Beyond wCDM Evolving models of dark energy:
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Beyond wCDM Evolving models of dark energy: Olive: 6 double source plane lenses Grey: Planck (Forecast, including polarization and weak lensing constraints) Black: combination

22 Beyond wCDM Evolving models of dark energy:
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Beyond wCDM Evolving models of dark energy: Olive: 6 double source plane lenses Grey: Planck (Forecast, including polarization and weak lensing constraints) Black: combination FoM = 6.17π/A95 = 14.2 WMAP plus Union SNe → 15 (Mortonson+2010)

23 Constraining Dark Energy with Double Source Plane Strong Lenses
Thomas Collett

24 Constraining Dark Energy with Double Source Plane Strong Lenses
Thomas Collett

25 ~105 galaxy scale strong lenses (based on COSMOS )
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett ~105 galaxy scale strong lenses (based on COSMOS ) 1 in galaxy scale lenses will be doubles (Gavazzi+ 2008) Expect at least hundreds! (maybe even thousands)

26 At least ... ~105 galaxy scale strong lenses (based on COSMOS )
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett ~105 galaxy scale strong lenses (based on COSMOS ) 1 in galaxy scale lenses will be doubles (Gavazzi+ 2008) Expect at least hundreds! (maybe even thousands) At least ...

27 Black: 6 lenses, Ωk = 0 FoM = 14.2 Red: 100 lenses, Ωk ≠ 0 FoM = 38
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Black: 6 lenses, Ωk = 0 FoM = 14.2 Red: 100 lenses, Ωk ≠ 0 FoM = 38

28 (Other cool science we can do with double source plane lenses)
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Systematics (Other cool science we can do with double source plane lenses)

29 Systematics Mass between the two rings Mass of the intermediate source
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Systematics Mass between the two rings Mass of the intermediate source Mass along the line of sight

30 Systematics Mass between the two rings Mass of the intermediate source
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Systematics Mass between the two rings Mass of the intermediate source Mass along the line of sight

31 Systematics If ignored 1-10% systematic error, detectable effect
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Systematics If ignored 1-10% systematic error, detectable effect → Include in model. Sonnenfeld+ 2012 Mass between the two rings Mass of the intermediate source Mass along the line of sight

32 Systematics Fit more complicated mass models
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Systematics Fit more complicated mass models Suyu+2013, Sonnenfeld+ 2012 Mass between the two rings Mass of the intermediate source Mass along the line of sight

33 Systematics Mass between the two rings Mass of the intermediate source
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Systematics Mass between the two rings Mass of the intermediate source Mass along the line of sight Undetectable in the lens model. Less important than for time-delays. Have to infer mass along the line of sight by prescribing dark matter halos to galaxies. Collett % precision on η achievable. Talk to me if you're interested in individual objects at z>1

34 Constraining Dark Energy with Double Source Plane Strong Lenses
Thomas Collett Summary Double source plane lenses provide another way to probe dark energy. A simple geometrical probe, with independent systematics and no h dependence A handful of double source plane systems have the potential to provide 10 percent constraints on w Hundreds of double source plane lenses will be discovered in the near future → FoM ~ 40+ We can control systematics with flexible models and precise reconstructions of the line of sight

35 Constraining Dark Energy with Double Source Plane Strong Lenses
Thomas Collett Spare Slides

36 Perturbations by the intermediate source
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Perturbations by the intermediate source Infer the mass of high redshift galaxies If completely neglected: LMC: ~1% systematic error on η MW: ~10% systematic error on η Effect is detectable: include in the lens model. (Sonnenfeld+ 2012, Fixed cosmology, photometric zs2)

37 Density profile of massive galaxies:
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Density profile of massive galaxies: Probe of Baryonic feedback This uncertainty dominates the statistical error. Effect of deviations from power-law seem to be small (Sonnenfeld+ 2012, Fixed cosmology, photometric zs2)

38 Perturbations by structures along the line of sight
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Perturbations by structures along the line of sight Part of the effect cancels; less significant than for time-delay cosmography Infer mass along the line of sight: Collett+ 2013 Width of ensemble P(κext) 1% precision

39 What about the assumption of flatness?
Constraining Dark Energy with Double Source Plane Strong Lenses Constraining Dark Energy with Double Source Plane Strong Lenses Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Thomas Collett 39 39 39 What about the assumption of flatness? Ωk ≠ 0 Ωk ≡ 0

40 What if we can't measure the ratio of Einstein radii to 1%?
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett What if we can't measure the ratio of Einstein radii to 1%? 1. Compound lensing – the intermediate source has mass 2. The lens is an astrophysical object – they aren't perfectly isothermal or perfectly spherical

41 Cosmology with a population of systems.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Cosmology with a population of systems. SLACS: 1.1mm, S > 1 mJy → ~1.5 double source plane systems (1.5 in 78) 1.1mm, S > 0.3 mJy → ~3 double source plane systems (3 in 78) But can be more efficient if you focus only on the most massive lenses.

42 Constraints with 6 systems.
Constraining Dark Energy with Double Source Plane Strong Lenses Thomas Collett Thomas Collett Constraints with 6 systems. Pick the set of systems that provided the median constraints on w. WMAP+6 systems is ~2.5 times better than WMAP+1. WMAP+ 1 system wDE = −0.99 ± 0.27 6 systems wDE = −1.01 ± 0.11 WMAP+BAO+Time Delay+ 6 systems wDE = −1.04 ± 0.09

43 Constraining Dark Energy with Double Source Plane Strong Lenses
43 43 43 Planck+6

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