Deep sub-arcsecond widefield imaging of the Lockman Hole field at 144 MHz

TL;DR

This paper demonstrates the first widefield sub-arcsecond imaging at low radio frequencies, overcoming ionospheric challenges to produce high-resolution maps of the Lockman Hole at 144 MHz, enabling detailed studies of distant astrophysical sources.

Contribution

It introduces a novel method for widefield low-frequency imaging with sub-arcsecond resolution by applying ionospheric corrections during imaging, validated on LOFAR data.

Findings

Produced a 7.4 deg² 144 MHz map at 0.3'' resolution

Achieved sensitivity of 25 μJy/beam near phase center

Utilized 250,000 core hours on available computing resources

Abstract

High quality low-frequency radio surveys have the promise of advancing our understanding of many important topics in astrophysics, including the life cycle of active galactic nuclei (AGN), particle acceleration processes in jets, the history of star formation, and exoplanet magnetospheres. Currently leading low-frequency surveys reach an angular resolution of a few arcseconds. However, this resolution is not yet sufficient to study the more compact and distant sources in detail. Sub-arcsecond resolution is therefore the next milestone in advancing these fields. The biggest challenge at low radio frequencies is the ionosphere. If not adequately corrected for, ionospheric seeing blurs the images to arcsecond or even arcminute scales. Additionally, the required image size to map the degree-scale field of view of low-frequency radio telescopes at this resolution is far greater than what typical soft- and hardware is currently capable of handling. Here we present for the first time (to the best of our knowledge) widefield sub-arcsecond imaging at low radio frequencies. We derive ionospheric corrections in a few dozen individual directions and apply those during imaging efficiently using a recently developed imaging algorithm (arXiv:1407.1943, arXiv:1909.07226). We demonstrate our method by applying it to an eight hour observation of the International LOw Frequency ARray (LOFAR) Telescope (ILT) (arXiv:1305.3550). Doing so we have made a sensitive $7.4\ \mathrm{deg}^2$ $144\ \mathrm{MHz}$ map at a resolution of $0.3''$ reaching $25\ \mu\mathrm{Jy\ beam}^{-1}$ near the phase centre. The estimated $250,000$ core hours used to produce this image, fit comfortably in the budget of available computing facilities. This result will enable future mapping of the entire northern low-frequency sky at sub-arcsecond resolution.