On the projected mass distribution around galaxy clusters . A Lagrangian theory of harmonic power spectra
Abstract
Aims: Gravitational lensing allows us to quantify the angular distribution of the convergence field around clusters of galaxies to constrain their connectivity to the cosmic web. We describe the corresponding theory in Lagrangian space in which analytical results can be obtained by identifying clusters to peaks in the initial field.
Methods: We derived the threepoint Gaussian statistics of a twodimensional (2D) field and its first and second derivatives. The formalism allowed us to study the statistics of the field in a shell around a central peak, in particular its multipolar decomposition.
Results: The peak condition is shown to significantly remove power from the dipolar contribution and to modify the monopole and quadrupole. As expected, higher order multipoles are not significantly modified by the constraint. Analytical predictions are successfully checked against measurements in Gaussian random fields. The effect of substructures and radial weighting is shown to be small and does not change the qualitative picture.The nonlinear evolution is shown to induce a nonlinear bias of all multipoles proportional to the cluster mass.
Conclusions: We predict the Gaussian and weakly nonGaussian statistics of multipolar moments of a 2D field around a peak as a proxy for the azimuthal distribution of the convergence field around a cluster of galaxies. A quantitative estimate of this multipolar decomposition of the convergence field around clusters in numerical simulations of structure formation and in observations will be presented in two forthcoming papers.
 Publication:

Astronomy and Astrophysics
 Pub Date:
 September 2017
 DOI:
 10.1051/00046361/201630091
 arXiv:
 arXiv:1701.01335
 Bibcode:
 2017A&A...605A..80C
 Keywords:

 largescale structure of Universe;
 galaxies: clusters: general;
 gravitational lensing: weak;
 methods: analytical;
 methods: statistical;
 Astrophysics  Cosmology and Nongalactic Astrophysics
 EPrint:
 13 pages, matched version accepted for publication in A&