Into the depths: Unveiling ELAIS-N1 with LOFAR's deepest sub-arcsecond wide-field images

TL;DR

This paper presents the deepest sub-arcsecond wide-field LOFAR images of ELAIS-N1, achieved through improved calibration and data processing, revealing more objects with less observing time and demonstrating the potential of international LOFAR arrays.

Contribution

The study introduces enhanced calibration techniques and processing methods that enable ultra-deep, high-resolution LOFAR imaging with reduced computational costs.

Findings

Achieved a 14 μJy/beam noise level at 0.3" resolution, doubling previous depth.

Uncovered four times more objects than previous deep field images at similar resolution.

Reduced computational costs by nearly half compared to earlier LOFAR imaging efforts.

Abstract

We present the deepest wide-field 115-166 MHz image at sub-arcsecond resolution spanning an area of 2.5 by 2.5 degrees centred at the ELAIS-N1 deep field. To achieve this, we improved the calibration for the International LOFAR Telescope. This enhancement enabled us to efficiently process 32 hrs of data from four different 8-hr observations using the high-band antennas (HBAs) of all 52 stations, covering baselines up to approximately 2,000 km across Europe. The DI calibration was improved by using an accurate sky model and refining the series of calibration steps on the in-field calibrator, while the DD calibration was improved by adopting a more automated approach for selecting the DD calibrators and inspecting the self-calibration on these sources. We also added an additional round of self-calibration for the Dutch core and remote stations in order to refine the solutions for shorter baselines. To complement our highest resolution at 0.3", we also made intermediate resolution wide-field images at 0.6" and 1.2". Our resulting wide-field images achieve a central noise level of 14 muJy/beam at 0.3", doubling the depth and uncovering four times more objects than the Lockman Hole deep field image at comparable resolution but with only 8 hrs of data. Compared to LOFAR imaging without the international stations, we note that due to the increased collecting area and the absence of confusion noise, we reached a point-source sensitivity comparable to a 500-hr ELAIS-N1 6" image with 16 times less observing time. Importantly, we have found that the computing costs for the same amount of data are almost halved (to about 139,000 CPU hrs per 8 hrs of data) compared to previous efforts, though they remain high. Our work underscores the value and feasibility of exploiting all Dutch and international LOFAR stations to make deep wide-field images at sub-arcsecond resolution.