Constraints on Cosmic Birefringence from SPIDER, Planck, and ACT observations

Abstract

The Early Dark Energy (EDE) model has been proposed as a candidate mechanism to generate cosmic birefringence through a Chern-Simons coupling between a dynamical scalar field and the cosmic microwave background (CMB) photon. Such birefringence induces a nonzero cross-correlation between the CMB E- and B-modes, providing a direct observational signature of parity violation. Recent measurements of the EB and TB power spectra, however, cannot yet unambiguously separate instrumental miscalibration (α) from a true cosmic-rotation angle (β). For this reason, we perform a model-independent analysis in terms of the total effective rotation angle α+β. We analyze the latest EB and TB measurements from the SPIDER, Planck, and ACT experiments and derive constraints on the Chern-Simons coupling constant gMPl and on the polarization rotation angle α+β. We find that the coupling gMPl is not compatible with the SPIDER data, while it provides reasonable fits to the Planck and ACT measurements. The fits for α+β prefer a value larger than zero: when combined, Planck+ACT yield a detection significance of approximately 7σ. We also find that ACT data alone do not provide sufficiently tight constraints on either gMPl or α+β, whereas the combination Planck+ACT improves the statistical consistency of ACT's high- results and leads to a better PTE for those measurements.

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