Peculiar Velocity Decomposition, Redshift Space Distortion and Velocity Reconstruction in Redshift Surveys - I. The Methodology

TL;DR

This paper introduces a novel velocity decomposition method to improve redshift space distortion modeling and enhance 3D peculiar velocity reconstruction in galaxy surveys, addressing systematic errors in structure growth measurements.

Contribution

It proposes a unique, physically motivated velocity decomposition scheme that simplifies RSD modeling and accounts for higher-order corrections without extra uncertainties.

Findings

Derived a new redshift space power spectrum formula.

Identified a systematic underestimation of the growth rate parameter f.

Clarified the origins of the finger of God effect.

Abstract

Massive spectroscopic surveys will measure the redshift space distortion (RSD) induced by galaxy peculiar velocity to unprecedented accuracy. We develop a new method to improve the RSD modeling and to carry out robust reconstruction of the 3D large scale peculiar velocity through galaxy redshift surveys, in light of RSD. (1) We propose a mathematically unique and physically motivated decomposition of peculiar velocity into three eigen-components of different origins, different scale dependences and different impacts on RSD. (2) This decomposition has the potential to simplify and improve the RSD modeling. We derive a new formula for the redshift space power spectrum. Under the velocity decomposition scheme, all high order Gaussian corrections and non-Gaussian correction of order $\delta^3$ can be taken into account without introducing extra model uncertainties. We find that the leading order contribution $\propto (1+f\tilde{W}(k)u^2)^2$ differs from the Kaiser formula by a function $\tilde{W}(k)\leq 1$. We hence identify a significant systematic error causing underestimation of the structure growth parameter $f$ by as much as $O(10%)$ even at relatively large scale $k=0.1h/$Mpc. The velocity decomposition also reveals the three origins of the finger of God (FOG) effect. (3) The velocity decomposition clarifies issues in peculiar velocity reconstruction through 3D galaxy distribution. We discuss two possible ways to carry out the velocity reconstruction. Both use the otherwise troublesome RSD in velocity reconstruction as a valuable source of information. Both have the advantage to render the reconstruction of a stochastic 3D field into the reconstruction of a deterministic window function $W^s(k,u)$ of limited degrees of freedom...[abridged]