Power Spectra Based Planck Constraints on Compensated Isocurvature, and Forecasts for LiteBIRD and CORE Space Missions

Abstract

Compensated isocurvature perturbations (CIP), where the baryon and cold dark matter perturbations cancel, do not cause total matter isocurvature perturbation. Consequently, at the linear order in the baryon density contrast , CIP is not detectable by the CMB power spectra. At the second order CIP smoothes the power spectra in a similar manner as lensing, causing a degeneracy between the CIP variance 2rms=<2> and lensing parameter AL. We show that the CMB lensing data breaks this degeneracy. Nested sampling of the LCDM+CIP(+AL) model, the Planck 2015 temperature, polarization, and lensing data give 2rms=0.00690.0030 at 68% CL. A non-zero value is favored at 2.3σ. CIP with 2rms=0.007 improves the bestfit 2 by 3.6 compared to the adiabatic LCDM model. In contrast, although the temperature data favor AL=1.22, allowing AL1 does not improve the joint fit, since the lensing data disfavor AL1. Indeed, CIP provides a rare example of a simple model, which can reduce the Planck lensing anomaly by fitting well simultaneously the high multipole temperature and lensing data, as well as the polarization data. Finally, we derive forecasts for future satellite missions (LiteBIRD proposal to JAXA and Exploring Cosmic Origins with CORE proposal to ESA's M5 call). Due to its coarse angular resolution, LiteBIRD is not able to improve the constraints on CIP or AL, but CORE-M5 approaches the cosmic variance limit and improves the CIP constraint to 2rms<0.0006\ (0.0014) at 68% (95%) CL, which is 9 times better than the current trispectrum based upper bound and 6 times better than obtained from the simulated Planck data. In addition, CORE-M5 will exquisitely distinguish between CIP and AL. No matter whether CIP is allowed for or not, the uncertainty of the lensing parameter will be σ(AL)=0.012.