%ALu, Tianhuan%AHaiman, Zoltán%AZorrilla Matilla, José%BJournal Name: Monthly Notices of the Royal Astronomical Society; Journal Volume: 511; Journal Issue: 1; Related Information: CHORUS Timestamp: 2023-01-28 05:22:28 %D2022%IOxford University Press %JJournal Name: Monthly Notices of the Royal Astronomical Society; Journal Volume: 511; Journal Issue: 1; Related Information: CHORUS Timestamp: 2023-01-28 05:22:28 %K %MOSTI ID: 10362545 %PMedium: X %TSimultaneously constraining cosmology and baryonic physics via deep learning from weak lensing %XABSTRACT

Ongoing and planned weak lensing (WL) surveys are becoming deep enough to contain information on angular scales down to a few arcmin. To fully extract information from these small scales, we must capture non-Gaussian features in the cosmological WL signal while accurately accounting for baryonic effects. In this work, we account for baryonic physics via a baryonic correction model that modifies the matter distribution in dark matter-only N-body simulations, mimicking the effects of galaxy formation and feedback. We implement this model in a large suite of ray-tracing simulations, spanning a grid of cosmological models in Ωm−σ8 space. We then develop a convolutional neural network (CNN) architecture to learn and constrain cosmological and baryonic parameters simultaneously from the simulated WL convergence maps. We find that in a Hyper-Suprime Cam-like survey, our CNN achieves a 1.7× tighter constraint in Ωm−σ8 space (1σ area) than the power spectrum and 2.1× tighter than the peak counts, showing that the CNN can efficiently extract non-Gaussian cosmological information even while marginalizing over baryonic effects. When we combine our CNN with the power spectrum, the baryonic effects degrade the constraint in Ωm−σ8 space by a factor of 2.4, compared to the much worse degradation by a factor of 4.7 or 3.7 from either method alone.

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