Constraining Quasar and IGM Properties Through Bubble Detection in Redshifted 21-cm Maps

Abstract

The infrared detection of a z>7 quasar has opened up a new window to directly probe the IGM during the epoch of reionization. In this paper we theoretically consider the possibility of detecting the ionized bubble around a z=8 quasar using targeted redshifted 21-cm observations with the GMRT. The apparent shape and size of the ionized bubble, as seen by a distant observer, depends on the parameters Nphs/C, xHI/C and τQ where Nphs, τQ, xHI and C are respectively the photon emission rate, age of the quasar, the neutral fraction and clumping factor of the IGM.Here we have analytically estimated the shape and size of a quasar's ionized bubble assuming an uniform IGM and ignoring other ionizing sources besides the quasar, and used this as a template for matched filter bubble search with the GMRT visibility data. We have assumed that Nphs is known from the infrared spectrum and C from theoretical considerations, which gives us two free parameters xHI and τQ for bubble. Considering 1,000 hr of observation, we find that there is a reasonably large region of parameter space where a 3σ detection is possible. We also find that it will be possible to place lower limits on xHI and τQ with this observation. Deeper follow up observations can place upper limits on τQ and xHI. Value of C affect the estimation of xHI but the estimation of τQ remains unaffected.We have used a semi-numerical technique to simulate the apparent shape and size of quasar ionized bubbles considering the presence of other ionizing sources and inhomogeneities in the IGM. The presence of other sources increase the size of the quasar bubble, leading to underestimation of xHI. Clustering of other ionizing sources around the quasar can produce severe distortions in bubble's shape. However, this does not severely affect parameter estimation in the bubbles that are large.