Importance of high-frequency bands for thermal dust removal in ECHO

TL;DR

This study evaluates the importance of high-frequency bands in the ECHO CMB mission for effectively removing thermal dust foregrounds, demonstrating that frequencies up to 600 GHz significantly improve foreground subtraction and sensitivity.

Contribution

It provides a detailed analysis of how adding high-frequency bands enhances foreground removal and measurement sensitivity in the ECHO mission, using multiple dust models.

Findings

Adding high-frequency bands reduces residual foreground and noise levels.

Most improvements occur within the 28-600 GHz range.

Extending to 850 GHz yields negligible additional benefits.

Abstract

The Indian Consortium of Cosmologists has proposed a cosmic microwave background (CMB) space mission, Exploring Cosmic History and Origin (ECHO). A major scientific goal of the mission is to detect the primordial B-mode signal of CMB polarization. The detection of the targeted signal is very challenging as it is deeply buried under the dominant astrophysical foreground emissions of the thermal dust and the Galactic synchrotron. To facilitate the adequate subtraction of thermal dust, the instrument design of ECHO has included nine dust-dominated high-frequency bands over the frequency range of 220-850 GHz. In this work, we closely reexamine the utility of the high-frequency ECHO bands in foreground subtraction using the Needlet Internal Linear Combination component separation method. We consider three dust models: a physical dust model, a dust spectral energy distribution (SED) with a single modified black body (MBB) emission law and a multilayer dust model with frequency-frequency decorrelation. We consider eleven ECHO bands in the 28-190 GHz range as our baseline configuration and investigate the changes in the level foreground and noise residuals as subsequent dust-dominated high-frequency bands are added. We find that adding the high-frequency bands leads to a consistent decrease in the level of residual foreground and noise, and the sensitivity of r measurement improves. Most of the reduction in both residual levels and enhancement in the sensitivity is achieved in the 28-600 GHz frequency range. Negligible change in residual levels is seen by extending the frequency range from 600 GHz to 850 GHz.