Multipolar structure of the local expansion rate from incomplete sky data
Abstract
Using the Cosmicflows-4 data, we reconstruct the first multipolar moments of a general function describing the local expansion rate. In addition to the conventional harmonic approach, we employ a basis of symmetric and trace-free tensors to characterize the anisotropies of the expansion rate, allowing us to identify all directions associated with each of its multipoles. Focusing on objects in z∈[0.01,0.05] in the CMB rest frame, we derive all 2+1 degrees of freedom in the multipoles =1,2 and 3, which are split into one amplitude and unit vectors per multipole. To mitigate anisotropies induced by incomplete sky coverage, we introduce a pixel-based mask that removes poorly sampled pixels. The full-sky expansion rate is reconstructed using two independent approaches: a pseudo-inverse of the multipole-coupling kernel induced by the mask, and a maximum-likelihood estimate of the underlying full-sky field. These approaches are validated through simulations that explore different mask resolutions, cosmic variance and statistical noise. We find that the quadrupole and octupole amplitudes are consistent (at 95\% C.L.) with the expectations of a ΛCDM universe with linear and mild nonlinear perturbations, where the anisotropies of the expansion rate result from small peculiar velocities. The dipole amplitude, however, is inconsistent with ΛCDM predictions at 3.3σ, with a direction (l, b) = (290, -4) 5 consistent with a bulk flow. This signal comes predominantly from sources in z∈[0.03,0.05]. Finally, we conduct alignment tests between the dipole, quadrupole, and octupole vectors. We confirm recent findings showing that the maxima of these multipoles are approximately located at (290,-4). However, detailed tests using the complete vector structure of these multipoles reveal no evidence of alignments.
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