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"Dark clumps" near clusters from Weak Lensing Effects Zuhui Fan Dept. of Astronomy, Peking University. Outline: Introduction Noise peaks from intrinsic ellipticites Results Summary. Introduction Gravitational lensing effects arise from the light deflection by the
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"Dark clumps" near clustersfrom Weak Lensing Effects Zuhui Fan Dept. of Astronomy, Peking University
Outline: • Introduction • Noise peaks from intrinsic ellipticites • Results • Summary
Introduction Gravitational lensing effects arise from the light deflection by the intervening structures
Weak Lensing Effects Weak distortions caused by the large-scale structures of the universe: common but weak • “see” the dark matter directly powerful probes of the distribution of dark matter • sensitive to the formation of large-scale structures and the global geometry of the universe highly promising in dark energy studies
Observationally challenging accurate shape measurements: lensing induced shape distortions are much weaker than the intrinsic ellipticities of galaxies statistical measurements of the coherent distortions PSF corrections accurate calibration of the redshift distribution of source galaxies
Observational advances Statistical methods theoretical studies Fast developing forefront of research
Cosmological Applications map out constrain cosmology dark matter distribution
“Dark clumps” around clusters Erben et al 2000 Linden et al. 2006 “Dark clumps” S/N ~4 M~1014Msun at z~0.2 If real, would be significant for the theory of structure formation
Galaxies are not intrinsically spherical shear intrinsic ellipticites
-> noise in the mass distribution constructed from weak lensing effects pure noise
Noise peaks from intrinsic ellipticities • Noise peaks have no optical counterparts (However, Dark clumps) • Lensing signals from real clumps have certain redshift dependency -- lensing tomography • On average, high S/N noise peaks (>4) are rare Use average number density of noise peaks: P~8*10-3(>4.5) Unlikely to be a noise peak, then real “dark clumps”? However, around real clusters, the probability of high noise peaks can be higher than average
-> Presence of real clusters affects the statistics of noise peaks Smoothed noise field can well be discribed by a Gaussian random field
Smoothed quantities: dpend on cluster profiles cored isothermal NFW
NFW ISO • Results : Rc=Rs=1.7 arcmin, Rvir=5Rc (Rs), θG=0.5arcmin, peak height=5.6 Profiles peak numbers in R>Rc (Rs)
κ reconstruction: mass-sheet degeneracy <K>=0 within the survey area <K >=0 for the outer most ring --> depend on survey area For a survey area much larger than the typical size of a cluster, the mass-sheet degeneracy does not affect much.
different normalizations on K cored isothermal NFW <K>=0 K=0(ring) true
Number of high S/N noise peaks are significantly boosted (~10 times for S/N>4.5 for cored isothermal cluster with <K>=0 within 5Rc)
Noise peaks above certain threshold are closely correlated with clusters, in a way similar to the biased halo formation. However, the mass- sheet degenerancy in weak lensing reconstruction should be taken into account. ---> To evaluate the probability of noise peaks, one must consider the cluster evironment ---> For large scale surveys, the correlation of clusters and noise peaks may cause contaminations on cluster correlations
Around a real cluster -> Noise affects cluster lensing signals cluster peak height νbiased by ~+1 for cored iso
Cluster peak height distribution With central , one can calcuate the distribution --> provide an analytical way to make a better prediction of cluster abundance from weak lensing surveys * (Hamana et al. 2004, fitting formula)
Summary * noise peaks and clusters are correlated * One must consider both coherently in weak lensing studies --> enhance the probability of high noise peaks (can be an order of magnitude higher) ---> true peak height is affected: cluster abundance