Towards 21-cm Intensity Mapping at \(z=2.28\) with uGMRT using the Tapered Gridded Estimator I: Foreground Avoidance

The post-reionization \((z \le 6)\) neutral hydrogen (HI) 21-cm intensity mapping signal holds the potential to probe the large scale structures, study the expansion history and constrain various cosmological parameters. Here we apply the Tapered Gridded Estimator (TGE) to estimate \(P(k_{\perp},k_{...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2022-08
Main Authors: Pal, Srijita, Kh Md Asif Elahi, Bharadwaj, Somnath, Ali, Sk Saiyad, Choudhuri, Samir, Ghosh, Abhik, Chakraborty, Arnab, Datta, Abhirup, Roy, Nirupam, Choudhury, Madhurima, Dutta, Prasun
Format: Article
Language:English
Subjects:
Avoidance
Brightness temperature
Field of view
Ionization
Mapping
Parameters
Sky surveys (astronomy)
Visibility
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The post-reionization \((z \le 6)\) neutral hydrogen (HI) 21-cm intensity mapping signal holds the potential to probe the large scale structures, study the expansion history and constrain various cosmological parameters. Here we apply the Tapered Gridded Estimator (TGE) to estimate \(P(k_{\perp},k_{\parallel})\) the power spectrum of the \(z = 2.28\) \((432.8\, {\rm MHz})\) redshifted 21-cm signal using a \(24.4\,{\rm MHz}\) sub-band drawn from uGMRT Band 3 observations of European Large-Area ISO Survey-North 1 (ELAIS-N1). The TGE allows us to taper the sky response which suppresses the foreground contribution from sources in the periphery of the telescope's field of view. We apply the TGE on the measured visibility data to estimate the multi-frequency angular power spectrum (MAPS) \(C_{\ell}(\Delta\nu)\) from which we determine \(P(k_{\perp},k_{\parallel})\) using maximum-likelihood which naturally overcomes the issue of missing frequency channels (55 \% here). The entire methodology is validated using simulations. For the data, using the foreground avoidance technique, we obtain a \(2\,\sigma\) upper limit of \(\Delta^2(k) \le (133.97)^2 \, {\rm mK}^{2}\) for the 21-cm brightness temperature fluctuation at \(k = 0.347 \, \textrm{Mpc}^{-1}\). This corresponds to \([\Omega_{\rm HI}b_{\rm HI}] \le 0.23\), where \(\Omega_{\rm HI}\) and \(b_{\rm HI}\) respectively denote the cosmic \HI mass density and the \HI bias parameter. A previous work has analyzed \(8 \, {\rm MHz}\) of the same data at \(z=2.19\), and reported \(\Delta^{2}(k) \le (61.49)^{2} \, {\rm mK}^{2}\) and \([\Omega_{\rm HI} b_{\rm HI}] \le 0.11\) at \(k=1 \, {\rm Mpc}^{-1}\). The upper limits presented here are still orders of magnitude larger than the expected signal corresponding to \(\Omega_{\rm HI} \sim 10^{-3}\) and \(b_{\rm HI} \sim 2 \).
ISSN:2331-8422
DOI:10.48550/arxiv.2208.11063