Cosmic shear results from CFHTLS Henk Hoekstra Ludo van Waerbeke Catherine Heymans Mike Hudson Laura Parker Yannick Mellier Liping Fu Elisabetta Semboloni.

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Presentation transcript:

Cosmic shear results from CFHTLS Henk Hoekstra Ludo van Waerbeke Catherine Heymans Mike Hudson Laura Parker Yannick Mellier Liping Fu Elisabetta Semboloni Martin Kilbinger

Observations of the (weak) gravitational lensing signal provide a powerful way to study the dark matter distribution in the universe.  It does not require assumptions about the dynamical state of the system under investigation.  It can probe the dark matter on scales where other methods fail, as it does not require visible tracers of the gravitational potential. Gravitational lensing

The large scale mass distribution causes a distortion in the shapes of background galaxies. This can lead to spectacular lensing examples… Gravitational lensing

A measurement of the ellipticity of a galaxy provides an unbiased but noisy measurement of the gravitational lensing shear What is weak lensing?

Cosmic shear is the lensing of distant galaxies by the overall distribution of matter in the universe: it is the most “common” lensing phenomenon. What is cosmic shear?

What do we measure? Underlying assumption: the galaxy position angles are uncorrelated in the absence of lensing 1.Measure the galaxy shapes from the images 2.Correct for observational distortions 3.Select a sample of background galaxies Lensing signal The conversion of the lensing signal into a mass requires knowledge of the source redshift distribution

What do we need? The weak lensing signal is small:  We need to measure the shapes of many galaxies.  We need to remove systematic signals at a high level of accuracy. Only recently we have been able to overcome both obstacles, although we still need various improvements to deal with the next generation of surveys

 1 square degree field of view  ~350 megapixels Megacam: Build a big camera…

Put it on a good telescope… Such as the CFHT or VST, LSST, SNAP, etc

… and take a lot of data! That’s when the “fun” starts… CFHTLS RCS2 KIDS

Dealing with systematics: the PSF Weak lensing is rather unique in the sense that we can study (PSF-related) systematics very well. Several diagnostic tools can be used. However, knowing systematics are present doesn’t mean we know how to deal with them… E-mode (curl-free) B-mode (curl)

Dealing with systematics: tests It is relatively easy to create simulated data to test the measurement techniques. The Shear TEsting Programme is an international collaboration to provide a means to benchmark the various methods. So far two papers have been published (Heymans et al., 2006 and Massey et al., 2007). These results provide a snapshot of the current accuracy that can be reached (~1-2%).

The Canada-France-Hawaii Telescope Legacy Survey is a five year project, with three major components. The Wide Survey’s focus is weak lensing. ~140 square degrees 4 fields 5 filters (u,g,r,i,z’) i<24.5 CFHT Legacy Survey

CFHTLS: current status Since the publication of the first results (Hoekstra et al. 2006) a number of things have improved: Reduced systematics Larger area observed (we can probe larger scales) Improve estimates of cosmological parameters using photo-z’s The latest results, based on the analysis of 57 sq. deg. spread over 3 fields will be published in Fu et al. (2007)

CFHTLS: the measurement Measurements out to 4 degree scales!

Cosmology is “scale independent”: non-linear corrections sufficient so far. CFHTLS: recent results

Results agree well with WMAP3!

What to do next? Currently ~35 sq. deg. of data have the full ugriz coverage and photometric redshift are being determined. With photometric redshift information for the sources we can study the growth of structure, which significantly improves the sensitivity to cosmological parameters.

Conclusions The measurement of the cosmic shear signal using CFHTLS data is progressing well. The use of photometric redshifts for the sources should lead to a dramatic improvement in the determination of cosmological parameters. BUT…

We need to improve our knowledge of: Source redshift distribution  photometric redshift from the survey data  deep (photometric) redshift surveys Non-linear power spectrum  large numerical simulations  good initial conditions Intrinsic alignments of galaxies  can be measured using photometric redshifts Observational systematic effects  Improved correction schemes  Detailed simulations There is some(?) work left…