Constraints on Phenomenological Amplitudes of CMB Anisotropy with Multi-Datasets

Abstract

Cosmic microwave background anisotropies encode crucial information about the early Universe and fundamental cosmological physics. Although the standard model provides a successful description of cosmic evolution, persistent cosmological tensions and subtle small-scale anomalies still challenge its internal consistency. In this paper, we investigate six phenomenological amplitude parameters Anew (new=L, SW, Dop, eISW, lISW, Pol) corresponding to the key effects related to CMB anisotropy: the Lensing, Sachs-Wolfe, Doppler, early Integrated Sachs-Wolfe, late Integrated Sachs-Wolfe, and Polarization effects, respectively. Using modified CAMB and Cobaya packages, we constrain the +Anew models with two data combinations: Planck+DESI+PantheonPlus (PDP) and Planck+ACT+DESI+PantheonPlus (PADP). Only the +AL is favored by AIC, with AL=1.0656-0.0303+0.0304 from PDP and AL=1.0795-0.0289+0.0260 from PADP, which implies 2.16σ and 3.06σ deviation from the model; values of ASW show 1.21σ and 1.96σ deviations to 1; AlISW is poorly constrained because the lISW effect has negligible influence at ≥ 30; and others are consistent with the model. Moreover, no noticeable improvement on the Hubble and σ8 tensions is found within these one-parameter extended scenarios. ACT DR6 high- data strengthens the +AL preference over the model, and reduces A Pol uncertainty by more than one order of magnitude, highlighting the importance of ground-based high- observations for future CMB analyses.