CMB-S4: Forecasting Constraints on fNL Through μ-distortion Anisotropy

Abstract

Diffusion damping of the cosmic microwave background (CMB) power spectrum results from imperfect photon-baryon coupling in the pre-recombination plasma. At redshift 5 × 104 < z < 2 × 106, the plasma acquires an effective chemical potential, and energy injections from acoustic damping in this era create μ-type spectral distortions of the CMB. These μ distortions trace the underlying photon density fluctuations, probing the primordial power spectrum in short-wavelength modes kS over the range 50 \ Mpc-1 k 104 \ Mpc-1. Small-scale power modulated by long-wavelength modes kL from squeezed-limit non-Gaussianities introduces cross-correlations between CMB temperature anisotropies and μ distortions. Under single-field inflation models, μ × T correlations measured from an observer in an inertial frame should vanish up to a factor of (kL/kS)2 1. Thus, any measurable correlation rules out single-field inflation models. We forecast how well the next-generation ground-based CMB experiment CMB-S4 will be able to constrain primordial squeezed-limit non-Gaussianity, parameterized by fNL, using measurements of Cμ T as well as Cμ E from CMB E modes. Using current experimental specifications and foreground modeling, we expect σ(fNL) 1000. This is roughly four times better than the current limit on fNL using μ × T and μ × E correlations from Planck and is comparable to what is achievable with LiteBIRD, demonstrating the power of the CMB-S4 experiment. This measurement is at an effective scale of k 740 \ Mpc-1 and is thus highly complementary to measurements at larger scales from primary CMB and large-scale structure.