Measuring cosmic bulk flow with kinetic Sunyaev-Zel'dovich velocity reconstruction

Abstract

Cosmic bulk flow--the volume-averaged peculiar velocity of matter--serves as a fundamental test of the Cosmological Principle when probed on gigaparsec (Gpc) scales. Historically, however, measurements of cosmic bulk flow have been limited to R 100\ h-1 Mpc. We present an application of kinetic Sunyaev-Zel'dovich (kSZ) velocity reconstruction to constrain the bulk flow on cosmological scales, over a volume of effective radius R2000\ h-1 Mpc. We use the WISE×SuperCOSMOS and unWISE galaxy catalogs, combined with CMB temperature maps from Planck to reconstruct large-scale velocities in six tomographic bins spanning 0.1 z 1.5. We place some of the tightest upper limits to date on bulk velocity at 200 R\,[h-1 Mpc] 2000, finding results fully consistent with the bulk flow expectation. Our unWISE constraints are in strong tension with the CatWISE quasar number-count dipole measurement if that dipole is due to a coherent bulk flow 370\ km\,s-1 at R1000\ h-1 Mpc. We also derive constraints on the matter power spectrum at low-k (k10-3\, Mpc-1) with low-z (z 1) galaxy samples. Alongside these cosmological constraints, we introduce a novel approach to map the optical depth bias--an inherent astrophysical degeneracy in kSZ velocity reconstruction--across different data combinations. Our work bridges the theoretical gap between bulk flow and kSZ-reconstructed velocities, and expands the horizon of bulk velocity measurements out to Gpc scales.