Quantifying the Redshift Space Distortion of the Bispectrum II: Induced Non-Gaussianity at Second Order Perturbation

Abstract

The anisotrpy of the redshift space bispectrum Bs(k1,k2,k3), which contains a wealth of cosmological information, is completely quantified using multipole moments Bm(k1,μ,t) where k1, the length of the largest side, and (μ,t) respectively quantify the size and shape of the triangle (k1,k2,k3). We present analytical expressions for all the multipoles which are predicted to be non-zero ( 8, m 6 ) at second order perturbation theory. The multipoles also depend on β1,b1 and γ2, which quantify the linear redshift distortion parameter, linear bias and quadratic bias respectively. Considering triangles of all possible shapes, we analyse the shape dependence of all of the multipoles holding k1=0.2 \, Mpc-1, β1=1, b1=1 and γ2=0 fixed. The monopole B00, which is positive everywhere, is minimum for equilateral triangles. B00 increases towards linear triangles, and is maximum for linear triangles close to the squeezed limit. Both B02 and B04 are similar to B00, however the quadrupole B02 exceeds B00 over a significant range of shapes. The other multipoles, many of which become negative, have magnitudes smaller than B00. In most cases the maxima or minima, or both, occur very close to the squeezed limit. Bm is found to decrease rapidly if or m are increased. The shape dependence shown here is characteristic of non-linear gravitational clustering. Non-linear bias, if present, will lead to a different shape dependence.