Constraining the Evolution of the HI Spin Temperature with Fast Radio Bursts

TL;DR

This paper explores the potential of using fast radio bursts (FRBs) to measure the HI spin temperature, offering a novel method to study neutral gas dynamics in distant galaxies despite current observational limitations.

Contribution

It demonstrates a proof of concept for constraining HI spin temperature using FRB observations and discusses how future telescopes can improve these measurements.

Findings

A 3σ upper limit on optical depth was established for a specific FRB.

Lower limits on HI spin temperature were derived from MeerKAT observations.

Future telescopes can significantly enhance the sensitivity to HI absorption signals.

Abstract

Fast radio bursts (FRBs) emit broad band radio wave radiation that may, in rare cases, encode atomic hydrogen (HI) absorption signals produced as they traverse the interstellar medium of their host galaxies. Combining such signals with high resolution HI emission maps offers a unique opportunity to probe the dynamics of neutral gas at cosmological distances through constraints of the HI excitation temperature $T_{spin}$, which characterises the balance of neutral gas phases and the underlying thermal processes within these galactic environments. While no absorption signal has been recorded in an FRB to date, we demonstrate a proof of concept with the bright (F = 35 Jy ms) and narrow (0.2 ms) FRB 20211127I detected by ASKAP. We find a 3${\sigma}$ upper limit on the integrated optical depth in the pulse-averaged spectrum of 33 km s$^{-1}$, and, based on the HI emission observed in a 3 hr MeerKAT L-band observation, subsequently find a lower limit on $T_{spin}$ of 26 K. While this test case provides little constraining power, we find that narrow, non-repeating FRBs with fluences greater than 20/70/150 Jy ms observed with all dishes with the current MeerKAT/ASKAP/DSA telescopes can probe integrated optical depths below 5 km s$^{-1}$. Furthermore, we highlight that utilising FAST's incredible sensitivity to stack thousands of bursts from hyperactive repeaters also provides a plausible avenue through which HI absorption, and hence $T_{spin}$, can be measured. Finally, we discuss how HI absorption can address several modern challenges in FRB science, providing a physical anchor for locating bursts within their host galaxies and helping to disentangle the host contribution to dispersion and scattering.