S IMBIG: The First Cosmological Constraints from Non-Gaussian and Non-Linear Galaxy Clustering
Abstract
The 3D distribution of galaxies encodes detailed cosmological information on the expansion and growth history of the Universe. We present the first cosmological constraints that exploit non-Gaussian cosmological information on non-linear scales from galaxy clustering, inaccessible with current standard analyses. We analyze a subset of the BOSS galaxy survey using S IMBIG, a new framework for cosmological inference that leverages high-fidelity simulations and deep generative models. We use two clustering statistics beyond the standard power spectrum: the bispectrum and a convolutional neural network based summary of the galaxy field. We infer constraints on parameters, b, h, ns, m, and σ8, that are 1.6, 1.5, 1.7, 1.2, and 2.3× tighter than power spectrum analyses. With this increased precision, we derive constraints on the Hubble constant, H0, and S8 = σ8 m/0.3 that are competitive with other cosmological probes, even with a sample that only spans 10% of the full BOSS volume. Our H0 constraints, imposing the Big Bang Nucleosynthesis prior on the baryon density, are consistent with the early time constraints from the cosmic microwave background (CMB). Meanwhile, our S8 constraints are consistent with weak lensing experiments and similarly lie below CMB constraints. Lastly, we present forecasts to show that future work extending S IMBIG to upcoming spectroscopic galaxy surveys (DESI, PFS, Euclid) will produce leading H0 and S8 constraints that bridge the gap between early and late time measurements and shed light on current cosmic tensions.
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