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Searching for the synchrotron cosmic web again: A replication attempt

Published online by Cambridge University Press:  04 April 2022

Torrance Hodgson*
Affiliation:
International Centre for Radio Astronomy Research (ICRAR), Curtin University, 1 Turner Ave, Bentley, WA 6102, Australia Curtin Institute for Computation, Curtin University, GPO Box U1987, Perth, WA 6845, Australia
Melanie Johnston-Hollitt
Affiliation:
Curtin Institute for Computation, Curtin University, GPO Box U1987, Perth, WA 6845, Australia
Benjamin McKinley
Affiliation:
International Centre for Radio Astronomy Research (ICRAR), Curtin University, 1 Turner Ave, Bentley, WA 6102, Australia ARC Centre of Excellence for All Sky Astrophysics in 3 Dimensions (ASTRO3D), Bentley, Australia
Natasha Hurley-Walker
Affiliation:
International Centre for Radio Astronomy Research (ICRAR), Curtin University, 1 Turner Ave, Bentley, WA 6102, Australia
*
Corresponding author: Torrance Hodgson, email: [email protected]
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Abstract

We follow up on the surprising recent announcement by Vernstrom et al. (2021, MNRAS) of the detection of the synchrotron cosmic web. We attempt to reproduce their detection with new observations with the Phase II, extended configuration of the Murchison Widefield Array at 118.5 MHz. We reproduce their detection methodology by stacking pairs of nearby luminous red galaxies (LRGs)—used as tracers for clusters and galaxy groups—contained in our low-frequency radio observations. We show that our observations are significantly more sensitive than those used in Vernstrom et al. and that our angular sensitivity is sufficient. And yet, we make no statistically significant detection of excess radio emission along the bridge spanning the LRG pairs. This non-detection is true both for the original LRG pair catalogue as used in Vernstrom et al., as well as for other larger catalogues with modified selection criteria. Finally, we return to the original data sets used in Vernstrom et al., and find that whilst we clearly reproduce the excess X-ray emission from ROSAT, we are not able to reproduce any kind of broad and extended excess intercluster filamentary emission using the original 118.5 MHz MWA survey data. In the interests of understanding this result, as part of this paper we release images of the 14 fields used in this study, the final stacked images, as well as key components of our stacking and modelling code.

Type
Research Article
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (https://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of the Astronomical Society of Australia

1. Introduction

The ‘cosmic web’ is a term used to evoke the structure of the Universe on the very largest of scales. In this model, dense clusters and galaxy groups are connected by diffuse filaments, forming a web like structure, and are interspersed with large, empty voids. Galaxy surveys have provided a strong empirical basis for this model (e.g. Baugh et al. Reference Baugh2004), whilst cosmological simulations have shown it to be a consequence of gravitational instabilities acting upon small density perturbations in the early Universe (e.g. Cen & Ostriker Reference Cen and Ostriker1999; Davé et al. Reference Davé2001). These same simulations, however, have predicted something more: that up to 40% of the baryonic content of the Universe resides along these filaments and around the periphery of clusters and galaxy groups, existing in a diffuse, highly ionised plasma, the so-called ‘warm-hot intergalactic medium’ (WHIM). To date, the WHIM has proven difficult detect, however a number of recent works in this area have made increasingly convincing claims to have made detection (see, e.g.: Eckert et al. Reference Eckert2015; Nicastro et al. Reference Nicastro2018; Tanimura et al. Reference Tanimura, Aghanim, Douspis, Beelen and Bonjean2019; Tanimura et al. Reference Tanimura2020; Macquart et al. Reference Macquart2020).

This sparse, weakly magnetised WHIM is also predicted to have an associated radio signature, the ‘synchrotron cosmic web’ (see: Brown Reference Brown2011; Vazza et al. Reference Vazza, Ferrari, Brüggen, Bonafede, Gheller and Wang2015; Vazza et al. Reference Vazza, Ettori, Roncarelli, Angelinelli, Brüggen and Gheller2019). As part of ongoing large-scale structure formation, cosmological simulations predict strong accretion shocks—having Mach numbers in the range $\mathcal{M} \sim$ 10–100)—from in-falling matter along filaments and around the outskirts of clusters. These shocks should be capable of accelerating the electrons from within the WHIM to high energies by way of diffusive shock acceleration and this population of high energy electrons, in turn, are expected to radiate this energy as synchrotron emission as they interact with weak intercluster magnetic fields. In this way, the cosmic web is expected to have a synchrotron radio signature that traces out accretion shocks along its boundaries. The detection and confirmation of this radio emission would allow us to validate models of the large-scale structure of the Universe, as well as giving us insight into the poorly understood intercluster magnetic environments at the sites of these shocks.

This synchrotron cosmic web, however, is predicted to be extremely faint and has proven especially difficult to detect. Large-scale magnetohydrodynamic simulations by Vazza et al. (Reference Vazza, Ettori, Roncarelli, Angelinelli, Brüggen and Gheller2019), for example, point to a large population of radio-relic-like shocks well below the level of direct detection of any current or future radio telescopes. Only a small fraction of the very brightest knots in these shocks rise to the level of direct detection, and these are located principally around the most massive galaxy clusters (Hodgson et al. Reference Hodgson, Vazza, Johnston-Hollitt and McKinley2021b). Vacca et al. (Reference Vacca2018) did in fact claim direct detection of numerous large-scale synchrotron sources associated with the cosmic web, but follow-up observations by Hodgson et al. (Reference Hodgson, Johnston-Hollitt, McKinley, Vernstrom and Vacca2020) rebuffed these claims. More recently, Govoni et al. (Reference Govoni2019) claimed the detection of a radio ‘ridge’ extending between clusters Abell 309 and 401, suggesting a diffuse, energetic and magnetised plasma extending between the merging clusters. Whilst this detection goes some way to validating our models, in this particular case the energy is provided by the merging dynamics of the clusters and is qualitatively different to the more general mechanisms of the synchrotron cosmic web.

Other attempts to detect the synchrotron cosmic web have turned to statistical detection techniques to reveal faint emission sources buried beneath the noise of our current observations. Foremost among these methods is the cross-correlation technique. This method involves constructing a ‘best guess’ kernel of the probable locations of cosmic web emission, and performing a radial cross-correlation of this kernel with the radio sky. A positive correlation at $0^\circ$ offset is, in theory, indicative of a detection. In this way, this method hopes to reduce the noise by effectively integrating over a large enough area of the sky. Both Brown et al. (Reference Brown2017) and Vernstrom et al. (Reference Vernstrom, Gaensler, Brown, Lenc and Norris2017) used cross-correlation methods, and both were unable to make a definitive detection. In the former study, no positive correlation was detected. In the latter, Vernstrom et al. (Reference Vernstrom, Gaensler, Brown, Lenc and Norris2017) did indeed report a correlation, however the association of other sources such as active galactic nucleii (AGNs), star forming galaxies (SFGs), and other cluster emission with their correlation kernel meant they were unable to attribute the peak at $0^\circ$ to the cosmic web alone.

Recently, however, Vernstrom et al. (Reference Vernstrom, Heald, Vazza, Galvin, West, Locatelli, Fornengo and Pinetti2021) (herein: V2021) have reported definitive detection of the synchrotron cosmic web using an alternative statistical method known as stacking. Their method attempted to measure the mean intercluster radio emission between pairs of close-proximity luminous red galaxies (LRGs). LRGs are known to have a strong association with the centre of clusters and galaxy groups (Hoessel, Gunn, & Thuan Reference Hoessel, Gunn and Thuan1980; Schneider, Gunn, & Hoessel Reference Schneider, Gunn and Hoessel1983; Postman & Lauer Reference Postman and Lauer1995). Close-proximity pairs of LRGs therefore are likely to indicate close-proximity overdense regions of our Universe, and in turn we expect some fraction of these to be connected by a filament. Thus, V2021 stacked hundreds of thousands of low-frequency radio images of such pairs, which were rotated and rescaled so as to align all pairs to a common grid, before being averaged so as to find the mean image. After subtracting out a model for the LRG and cluster contribution, they reported finding excess emission with $>\! 5 \sigma$ significance along the length of the intercluster region. Moreover, this excess was detected by two independent instruments—in the Galactic and Extragalactic All-sky MWAFootnote a survey (Wayth et al. Reference Wayth2015; Hurley-Walker et al. Reference Hurley-Walker2017b) and by the Owens Valley Radio Observatory Long Wavelength Array (OVRO-LWA; Eastwood et al. Reference Eastwood2018)—and across four frequencies ranging from 73–154 MHz. A null test, formed by stacking physically distant LRG pairs for which we do not expect a connecting filament to exist, returned no excess emission. After excluding multiple alternative explanations, V2021 suggested the most likely explanation for this excess intercluster signal was the cosmic web itself.

The result reported in V2021 is convincing, but it is also surprising. Previous intercluster magnetic field estimates provided upper limits on the order of just a few nG (e.g. Pshirkov, Tinyakov, & Urban Reference Pshirkov, Tinyakov and Urban2016; O’Sullivan et al. Reference O’Sullivan2019; Vernstrom et al. Reference Vernstrom, Gaensler, Rudnick and Andernach2019). However, the reported excess emission supports intercluster magnetic field strengths averaging 30–60n G, and moreover these estimates are strictly a lower limit as some significant fraction of stacked pairs will not in fact be connected by a filament. More recent follow-up work by Hodgson et al. (Reference Hodgson, Vazza, Johnston-Hollitt, Duchesne and McKinley2021a), which stacked a simulated radio sky—including cosmic web emission—from the FIlaments and Galactic RadiO (FIGARO; Hodgson et al. Reference Hodgson, Vazza, Johnston-Hollitt and McKinley2021b) simulation, failed to reproduce excess intercluster emission. With perfect knowledge of their simulated sky, this work stacked the known locations of dark matter halos rather than LRGs. They reported excess emission being detected on the immediate interior of halo pairs, associated with asymmetric accretion shocks onto clusters and galaxy groups, but no detectable emission along the true intercluster region. This work also explored the role of other contaminating sources, such as AGN, SFG, and radio halo populations, as well as the effect of sidelobes from the dirty interferometric beam, finding none of these to be significant. The discrepancy between V2021 and these simulated results, which build on our current best simulations of the cosmic web, remain difficult to explain.

Given the importance of the result of V2021, in this present study we attempt to reproduce and corroborate their result. We do so using the upgraded MWA Phase II instrument (Wayth et al. Reference Wayth2018), observing at 118 MHz, and take advantage of improvements to calibration and imaging pipelines that have appeared since the original GLEAM survey. We image 14 fields spanning the same LRG pairs as used in V2021, which we then stack using independent stacking and modelling pipelines. Our aim is to closely adhere to the methodology used in V2021 whilst seeking to measure the excess intercluster emission more accurately, thanks to the improved noise characteristics of our observations.

Throughout this paper, we assume a $\Lambda$ CDM cosmological model, with density parameters $\Omega_{\text{BM}} = 0.0478$ (baryonic matter), $\Omega_{\text{DM}} = 0.2602$ (dark matter), and $\Omega_{\Lambda} = 0.692$ , and the Hubble constant $H_0 = {67.8}\,\mathrm{Km\,s}^{-1}\,\mathrm{Mpc}^{-1}$ . All stated errors indicate one standard deviation.

2. Luminous red galaxy pairs

Only a few thousand clusters are currently catalogued with robust X-ray or Sunyaev–Zeldovich measurements (e.g. Piffaretti et al. Reference Piffaretti, Arnaud, Pratt, Pointecouteau and Melin2011; Planck Collaboration et al. 2016). This number is much smaller than the expected number of clusters and galaxy groups (e.g. Wen, Han, & Yang Reference Wen, Han and Yang2018), and is also too few to be useful for our present purposes as we do not expect the faint, intercluster emission to become detectable above our field noise after stacking so few images. Instead, as with V2021, we turn to using LRGs as a proxy for such overdense regions. LRGs are massive, especially luminous early-type galaxies, and are closely associated with overdense regions of the Universe. This association, however, comes with some caveats as explored in detail in Hoshino et al. (Reference Hoshino2015). To summarise briefly here, in the first instance not all massive clusters have a LRG as their central galaxy: for the most massive clusters the probability of this association peaks at 95%, however this association steeply drops off for lower mass systems, reaching just 70% for clusters of mass $M_{200} = 10^{14}\,{M_\odot}$ . An additional error introduced from the brightest LRGs located in clusters that do not align with the cluster centre, and this ‘miscentred’ fraction is substantial at 20–30%. Nonetheless, as with V2021, these caveats are acceptable given the vastly greater number of potential clusters that LRGs allow us to identify. It does, however, mean that any excess emission attributed to intercluster regions are strictly lower limits.

As with V2021, we use the LRG catalogue from Lopes (Reference Lopes2007). This catalogue incorporates approximately $1.4$ million LRGs extracted from the fifth data release of the Sloan Digital Sky Survey (York et al. Reference York2000), out to a redshift of $z < 0.70$ . Lopes (Reference Lopes2007) have used an empirical based method to calculate spectroscopic redshifts for this population from just three bands (gri), with an estimated error $\sigma = 0.027$ for $z < 0.55$ , and $\sigma = 0.040$ up to $z = 0.70$ .

In V2021, a list of LRG pairs was calculated that met the following set of conditions. First, the separation between the pairs was less than 15 Mpc. The metric used was the comoving distance, and this condition also included a lower bound of 1 Mpc (T. Vernstrom, personal communication). Additionally, the pairs were required to have an angular separation on the celestial sphere in the range ${20}^\prime < \theta < {180}^\prime$ . We find 1 078 730 such valid pairs, of which 601 435 ultimately overlap with our fields, and label this catalogue ‘Max 15 Mpc’. In Figure 1 we show the location of the LRG pair population on the celestial sphere, with those in red overlapping with our fields.

Figure 1. LRG pair distribution on the sky. The red points indicate pairs used in our stacks, whilst the grey are those pairs either outside our field or are within an exclusion zone.

V2021 reported finding just 390 808 pairs that satisfied these conditions. As it turns out, this reduced catalogue was the result of a bug in their code (T. Vernstrom, personal communication). Therefore, to compare like for like, we additionally include this abridged catalogue as ‘LRG-V2021’.

We also provide two additional catalogues of LRG pairs with differing selection criteria. In the first, we reduce the maximum spatial separation to 10 Mpc (‘Max 10 Mpc’), of which there are 270 458 (153 433 overlapping) entries. The motivation for this catalogue arises from our expectation that intercluster emission should be brighter for cluster pairs in closer proximity to each other where they are more likely to be interacting, possibly triggering pre- or post-merger shocks known to produce synchrotron emission. We also include a final catalogue with modified angular constraints, such that the minimum and maximum angular separations are shifted to ${15}^\prime$ and ${60}^\prime$ , respectively (‘Max ${60}^\prime$ ’). This catalogue contains 824 773 (436 899 overlapping) entries, and is motivated by concerns about resolving out large-scale angular structures, which is an aspect we discuss later in Subsection 5.2.

In Figure 2, we show the redshift, angular separation and spatial separation distributions of each of these LRG catalogues, for those LRG pairs that overlap with our fields and are included in our stacks. Note the double peak structure present in the redshift distribution of the Max 15 Mpc and Max ${60}^\prime$ catalogues: this is a function of the underlying distribution of the LRG catalogue which exhibits a small peak around $z = 0.08$ and much larger peak around $z = 0.5$ , combined with the effect at increasing redshifts of the duel constraints of the minimum angular separation and the maximum spatial separation. In the case of the 15 Mpc criterion, we find a mean redshift of $ \langle z\rangle = 0.185$ , a mean separation of $\langle r\rangle = {11.6}\, \mathrm{Mpc}$ , and a mean angular separation of $\langle {\theta}\rangle = {67}^\prime$ . The mean values for the other LRG pair catalogues are provided in Table 1.

Figure 2. The LRG pair distributions by redshift (left), angular separation (centre), and spatial separation (right), for each of the LRG pair catalogues used in our stacks.

Table 1. LRG pair statistics comparison between each of the LRG pair catalogues. We show the spatial and angular selection criteria for each catalogue, the number of LRG pairs that overlap with our fields (and the total pairs), their mean redshift, their mean angular separation, and their mean spatial separation, respectively. Spatial distances use a comoving metric.

*Due to an error in the work of V2021, the LRG-V2021 catalogue is an incomplete catalogue that nonetheless adheres to these ranges.

Table 2. A summary of the 14 fields imaged, observed by the MWA Phase II instrument at 118 MHz. The fields span the right ascension range ${120}^\circ$ to ${240}^\circ$ in ${20}^\circ$ increments, at declinations of ${3}^\circ$ and ${18}^\circ$ . We indicate the number of 112 s duration snapshots used in each field mosaic, and the resulting noise at the centre of the field. The model deviation describes the ratio of the measured flux density of sources after performing source finding, in comparison to the original calibration sky model; the $\mu$ term describes the mean values of these ratios, whilst $\sigma$ shows the standard deviation of these ratios.

3. Observations & data processing

3.1. Data selection

The original GLEAM survey, which was used in V2021, was observed using the MWA Phase I (Tingay et al. Reference Tingay2013). This consisted of 128 tiles positioned to give a maximum baseline of approximately 3 km when observing at zenith, and a large number of baselines under 100 m; when observing near the horizon these baselines are significantly foreshortened. The upgrade to the MWA Phase II (Wayth et al. Reference Wayth2015) in late 2017 was primarily a reconfiguration of the tile positions: the same 128 tiles were positioned to give an increased maximum baseline of almost 6 km as well as a much smoother distribution of baselines. The effect of these changes was to give Phase II almost twice the resolution as well as a better behaved dirty beam with reduced sidelobes, whilst otherwise leaving the point-source sensitivity unchanged. Sidelobe confusion is a major source of noise in Phase I observations, whereas in Phase II observations the higher resolution allows much deeper cleaning, which has flow on effects to further reduce image noise even when accounting for the resolution difference. In the observations used in this study, we take advantage of these improved characteristics of the MWA Phase II.

We have drawn our observations from those made in preparation for the upcoming GLEAM-X survey (Hurley-Walker et al. Reference Hurley-Walker, Seymour, Staveley-Smith, Johnston-Hollitt, Kapinska and McKinley2017a). GLEAM-X has observed the sky at frequencies ranging from 72–231 MHz in short duration ‘snapshots’ of approximately 2 min. These observation runs are typically observed at a fixed pointing in a ‘drift scan’ mode, where the celestial sphere is allowed to freely rotate through the primary beam.

We have identified 14 fields to image that best span the LRG population. These fields are centred at declinations of $\delta = \{+2^\circ, +18^\circ\}$ and spanning the right ascension range of $120^\circ \leq \alpha \leq 240^\circ$ at intervals of ${20}^\circ$ . From the archive of GLEAM-X observations, we filter for snapshots observed at 118.5 MHz and where their pointing centres are located near the centre of these 14 fields, with a tolerance $\alpha \pm 5^\circ$ and $\delta \pm 3^\circ$ . There are 512 observations that match this criteria, made during runs in 2018 February–March, 2018 May–June, 2019 January–February, and 2019 March. After calibration, imaging, and quality control checks, however, this number is reduced to 291 snapshots, constituting approximately 10 h of observations. In Table 2 we tabulate these 14 fields and some of their properties.

3.2. Data processing

All observations are centred at 118.5 MHz, of 112 s duration, spanning a bandwidth of 30.72 MHz, and correlated at a resolution of 10 kHz and 0.5 s. This is further averaged to 40 kHz and 4 s prior to calibration and imaging to ease data storage and processing requirements. All subsequent data processing occurs on a per snapshot basis until final mosaicing.

Calibration is performed using an in-field radio sky model. This sky model has been constructed in preparation for the GLEAM-X survey, and is principally based on the GLEAM sky catalogue. It does, however, include a number of additional sources, including better models for the so-called ‘A-team’ of extremely bright radio sources, such as Hydra A, Virgo A, Hercules A, and Centaurus A, all of which populate our fields. The GLEAM sky catalogue is known to have an error of 8.0(5)% up to declination ${18.5}^\circ$ , and an uncertainty of 11(2)% for more Northern declinations. We calibrate on all sources from this sky model that are within a ${20}^\circ$ radius of our field centre, and having a primary beam-attenuated apparent flux density of at least 700 mJy. These sources are predicted into the visibilities using the full embedded element primary beam model (Sokolowski et al. Reference Sokolowski2017).

Calibration is performed using the updated MWA calibrate tool,Footnote b which finds a full Jones matrix solution for each antenna, independently for each pair of channels, and with the solution interval set to the duration of the snapshot. Baselines longer than approximately 3.7 km are excluded from consideration during calibration, since these baselines are increasingly sensitive to angular scales of a higher resolution than the original GLEAM catalogue. Calibration solutions are visually inspected, and any antennae which have failed to well converge are flagged at this time. No self-calibration is performed, as in practice we have found this to be unnecessary.

Imaging is performed using wsclean (Offringa et al. Reference Offringa2014). We weight baselines using the Briggs formulation, with a robustness factor of +1; additionally baselines smaller than $15 \lambda$ , which are sensitive to emission on angular scales larger than ${3.8}^\circ$ , are excluded to avoid any kind of large-scale contamination from Galactic emission. Cleaning is then performed down to a threshold that depends on two factors: cleaning continues until first the ‘auto-mask’ threshold is reached, which is set at a factor of 3 times the residual map noise, and then cleaning continues only on those pixels previously cleaned down to the ‘auto-threshold’ limit, which we set as the estimated residual map noise. Typical values for the residual map noise of these individual snapshots is around 15–20 mJy. During imaging, we split the 30.72 MHz band into four equally sized channels to account for the typical flux density changes of sources over this frequency range due both to intrinsic properties and beam attenuation. We do, however, perform joint-channel cleaning, where clean peaks are chosen based on a full-bandwidth mean map, and the peak value is estimated using a linear fit across each output channel. Note that whilst wsclean does have multiscale clean functionality, we have chosen not to use this, so that any faint, extended emission sources remain in the residual maps after cleaning. We image and clean instrumental polarisations (e.g. XX, XY, YX, YY) independently, which is important since sources at this low elevation become strongly polarised as a result of the primary beam. These instrumental polarisation images are later combined based on the primary beam model to produce Stokes I images. Finally, after imaging is completed, we keep both the restored and residual Stokes I images for each snapshot for later processing: the restored map is used to verify and correct field calibration, whilst the residual map provides us with a point-source subtracted map to be ultimately used in stacking, without the need for complex wavelet subtraction techniques as used in V2021.

As a first order effect of ionospheric electron density variations, we observe direction-dependent shifts in the apparent position of radio sources, and these effects become increasingly strong at the low frequencies observed by the MWA. Without resolving this positional error, we not only risk introducing astrometric errors, but additionally sources in the final mosaic can appear blurred and point sources have a peak to integrated flux density ratio that is less than unity. To resolve this, typical MWA workflows make image-based corrections to ‘warp’ the image, and align the apparent position of sources with their position in the sky model (for example, see Hurley-Walker & Hancock Reference Hurley-Walker and Hancock2018). We follow this method by first source finding on the restored image using Aegean (Hancock, Trott, & Hurley-Walker Reference Hancock, Trott and Hurley-Walker2018), and cross-matching these sources with our sky model. We include only those sources that are isolated by at least ${1}^\prime$ radius from any other sky model source to avoid any ambiguous matches, and as a quality control check we require at least 200 cross-matches in a snapshot or else it is discarded. Then by measuring the angular offset of apparent position to that of the sky model, we interpolate across these deviations and thus warp the image to correct for this effect.

In an effort to match the sensitivity to extended emission of the MWA Phase II instrument to that of its Phase I counterpart, we proceed by convolving both the restored and residual images. At 118.5 MHz, a typical dirty beam size at Briggs +1 weighting has major and minor axes of approximately $2.3^\prime \times 1.8^\prime$ , whilst this size varies significantly by declination due to the foreshortening effect of the array at low elevations. We use miriad (Sault, Teuben & Wright Reference Sault, Teuben, Wright, Shaw, Payne and Hayes1995) to convolve each snapshot to a circularised resolution of ${3}^\prime$ , defined at zenith. We discuss the effects of this convolution step, and our sensitivity to extended emission, in Subsection 5.2.

Our snapshots are ready to be stacked and mosaiced. To do this we must first ensure all images are on the same projection, which are presently in a slant orthographic projection (‘SIN’) with the projection origin at each snapshot’s zenith. To minimise reprojection errors, which can be significant, we choose to reproject each snapshot onto the mean projection shared amongst the snapshots for a particular field, leaving the SIN projection origin approximately at the MWA zenith. We additionally mask the region within ${15}^\circ$ of the horizon for each snapshot, as these low-elevation observations are subject to significant errors. With these steps completed, we perform the weighted mean of all snapshots, with the weight based on the estimated local map noise $\sigma$ , as $\frac{1}{\sigma^2}$ .Footnote c A final quality check is included during this mosaicing step, whereby any snapshot with a map noise in excess of ${35}\, \mathrm{mJy\, beam}^{-1}$ (increased to ${45}\,\mathrm{mJy\, beam}^{-1}$ for field 14) is discarded. In this way, we create mosaics of the residuals, the restored images, as well as the estimated noise.

Finally, we verify our calibration by source finding on the final mosaic and comparing the measured flux density to the sky model flux density. As reported by Hurley-Walker et al. (Reference Hurley-Walker2017b), we observe a declination-dependent flux density error. In Figure 3, we present the kind of diagnostic used to check the flux density values for each field. For example, the top panel of this figure shows this error across field 10, showing the measured to model integrated flux density ratio increases from approximately unity to as high as 1.3 times at declination ${+30}^\circ$ . To correct for this effect, we model this error as a simple linear function of declination, as depicted by the dashed black line, and scale the image accordingly. The centre panel in Figure 3 shows the effect of this correction: the mean flux density ratio is reduced from 0.044 dex to –0.001 dex; the spread of ratios is reduced from a standard deviation of 0.0436 dex to 0.030 dex; and in this particular instance, the apparently bimodal distribution is corrected to appear much more normally distributed. As shown in Table 2, the mean flux density ratio across all fields is very nearly 0 dex after this correction, whilst the standard deviation lies in the range 0.021–0.037dex. These values are well within the stated errors of the GLEAM sky model. As a final sanity check, we also show in the lower panel of Figure 3 the ratio of peak to integrated flux density, where we can observe a good clustering of values around unity, suggesting that our ionospheric corrections are satisfactory.

Figure 3. Example calibration diagnostics for field 10, showing the declination correction. The 731 measured sources are compared to the calibration model. Prior to correction, their ratio has mean 0.044 dex and standard deviation 0.044 dex; after correction the mean becomes –0.001 dex and standard deviation 0.030 dex. Top: The measured to model flux density ratio, as a function of declination. The dashed line indicates the fit which is later used as an image-based correction. Centre: The distribution of measured to model flux density ratios for all 731 sources prior to (blue) and after (red) correction. Note in this case, the simple declination correction resolves the initial bimodal distribution. Bottom: The measured ratio of peak to integrated flux density, showing peak and integrated flux density of point sources are very nearly identical.

In Figure 4, we present a zoom of field 10, showing both the restored and residual images. The brightest source in this field is ${34.6}\,\mathrm{Jy\, beam}^{-1}$ . In the residual map, the estimated noise is just ${7.5}\,\mathrm{mJy\, beam}^{-1}$ , with a maximum value of ${41}\,\mathrm{mJy\, beam}^{-1}$ . The central residual map noise in the other fields is listed in Table 2.

Figure 4. The central region of field 10, centred at RA ${160}^\circ$ , Dec ${18}^\circ$ , with ${3}^\prime$ resolution. Left: The full mosaic, with all clean components restored into the image. The peak flux density in this image is ${3.8}\,\mathrm{Jy\, beam}^{-1}$ , whilst elsewhere in the field it is as high as ${34.6}\,\mathrm{Jy\, beam}^{-1}$ . Right: The residual image, with all clean components subtracted out. This inset has a mean noise of ${7.5}\,\mathrm{mJy\, beam}^{-1}$ , whilst the peak value is ${41}\,\mathrm{mJy\, beam}^{-1}$ .

Prior to stacking, we convert the residual maps from flux density (in units $\mathrm{Jy\, beam}^{-1}$ ) to temperature (units K), taking into account the spatially varying restoring beam dimensions. In this way, the stacked images are brought to have consistent units despite variable beam sizes, and this is consistent with the method employed in V2021.

3.3. Exclusion zones

We introduce a number of exclusion zones to our fields to improve the quality of our stacked images. In the first instance, during stacking we truncate around the edges of all fields where the beam power reaches less than 10% of its peak value. This excludes regions of high noise from being included in our stacks. Then, we visually inspect each field and identify areas to exclude based on two criteria. First, we check for extremely bright sources and draw exclusion zones around them, since their residuals tend to be areas of high noise. In the case of Virgo A, this exclusion zone is sizable in some fields as a result of small calibration errors throwing flux some distance away from the source. Secondly, we search for extended sources that remain in the residuals. Many of these are extended AGN sources that have been cleaned to the level of the noise in individual snapshots but which reappear above the noise once we mosaic, and appear as extended islands of emission typically a few beams in width. These visually inspected regions are collated and nulled in the image prior to stacking.Footnote d

4. Stacking and model subtraction

Having created deep, well-calibrated images of our 14 fields with point sources subtracted, we can now turn to stacking the LRG pairs. We stack LRG pairs in an effort to drive down the uncorrelated noise in our images, and meanwhile reveal any correlated mean emission that might bridge the LRG pairs. In this section we detail the construction both of these stacked images as well as the process used to construct the LRG models that we ultimately subtract in an effort to detect any excess cosmic web emission.

4.1. Stacking

We have implemented our stacking methodology similarly to V2021. We first identify a maximum scaling size, which is at least the maximum pixel distance of any single LRG pair across all fields. All halo pairs are subsequently strictly up-scaled to this size. We iterate though each LRG pair, once for each field. If the LRG pair is located within the field and does not overlap with an exclusion zone, we proceed to stack this pair. To do this, we identify the pixel coordinates of the pair within the field projection, and calculate both the pixel distance between these coordinates, as well as the angle between their connecting line and horizontal. We rotate and scale the pixel coordinates of the entire field such that pixel distance becomes the maximum pixel distance, and that their connecting line is rotated to horizontal. Finally, we linearly interpolate these values onto a rectangular grid whose centre is the point equidistant the LRG pair. This final map is now ready to be stacked alongside all other LRG pairs.

LRG pairs are weighted by a function of the estimated noise of the field. This estimated noise map is scaled and rotated identically to the field itself. When it comes time to stack, we weight each LRG pair by the inverse square of this map. Note that this noise map is spatially varying and, especially near the edges of the field where the underlying noise is rapidly changing, it is possible for the weighting used for a single LRG pair to vary across the length of the pair. We also track the sum of these weights, and in the final step divide the LRG pair stack by the weight stack to arrive at the weighted mean stack. See Appendix B for more detail on the stack weighting.

We construct a coordinate system on the final stacked images that places one LRG at $x = -1$ , the other at $x = +1$ , and the midpoint at the origin. The y direction is scaled identically, and we will herein refer to this as the normalised coordinate system.

At no point during stacking do we reproject the maps: they are rotated and scaled in pixel coordinates only. An alternative would have been to reproject each pair onto a common projection, but as we have noted earlier, our experience is that such reprojection creates scaling of the flux density values. Using pixel coordinates on an underlying SIN projection, however, has its own downsides whereby: geodesics on the sky are not, in general, straight lines in pixel coordinates; and the angular distance per pixel is not constant. In a SIN projection, these effects are most pronounced at the highest declinations where the field deviates most significantly from a Cartesian grid. They are, however, much smaller than the resolution element of the MWA. For example, in Figure 5, we consider the worst case scenario of an LRG pair at the maximum separation of ${180}^\prime$ , and at the most northern declination of ${+32}^\circ$ . The upper panel shows the transverse error that results from geodesics not being straight lines in pixel space which peaks at 0.003, whilst the lower panel shows the longitudinal error due to non-uniform pixel sizes which peaks at 0.01. The majority of our LRG pairs have a significantly smaller angular separation, and these errors are markedly smaller in these cases. These errors are small enough that we deem the simplicity and flux correctness of stacking in pixel space to be preferable.

Figure 5. The maximum error associated with treating a SIN projection as a simple Cartesian grid, obtained at the maximum declination ${+32}^\circ$ . Top: The maximum transverse error along a constant-declination ${180}^\prime$ line as a result of geodesics being curved in pixel space. Bottom: The maximum longitudinal error along a constant-hour-angle ${180}^\prime$ line, as a result of non-uniform pixel sizes.

Figure 6. An example showing the LRG model construction and subtraction from the stacked image, with all coordinates in the normalised coordinate system such that the LRG peaks are at $x = \{-1, 1\}$ and the y direction scales identically. Left: The original mean stacked image, with the dashed arcs indicating the exterior sweep over which each radially averaged one-dimensional model is constructed. The LRG peaks rise to just over 4 K; we have set the colour scale limits on these images to make the noise, at 24.6 mK, visible. Centre: The model sum map, produced by interpolating the one-dimensional model for each LRG peak onto the two-dimensional map. Right: The residual image, after subtracting the model from the original mean stack.

4.2. Model subtraction

Model construction is implemented identically to V2021. It is assumed that emission about each LRG peak, either due to radio emission from the LRG itself or nearby cluster emission, should be radially symmetric. Any cosmic web emission spanning the LRG pair will appear as an excess against this model. Thus, we construct our model based on the ${180}^\circ$ sweep exterior to the LRG pair and we radially average this to form a one-dimensional profile as a function of radial distance. The implementation of this involves binning pixels based on their radial distance, with the bin width set as 1 pixel, before each bin is then averaged. We can then create a function that linearly interpolates over these bins, allowing us to produce a full two-dimensional model independently for each LRG as a function of radial distance. Note by creating a model for each LRG peak independently, we are assuming the contribution from each peak is negligible for radial distances $r > 2$ . Finally, we sum the LRG model contribution for each peak to produce the final model.

We show an example of this process in Figure 6. In the left panel we show the original mean stacked image. The LRG peaks rise to just over 4 K, however we have set the colour scale limits on these images to make the noise, at 24.6 mK, visible. The dashed arcs indicate the exterior sweep over which each radially averaged one-dimensional model is constructed. These models are then linearly interpolated onto the two-dimensional map and summed, so as to produce the model, shown in the central panel. Finally, we produce the residual stack by subtracting out the model from the mean stack, shown in the rightmost panel. Note the absence of all large-scale structures in the residual, including the LRG peaks themselves as well as the surrounding depressions caused by the MWA dirty beam.

We additionally provide the results of a synthetic test of our stacking and modelling processes in Appendix A.

4.3. Noise characteristics

To determine the significance of any excess signal in the residual stack, it is necessary to characterise the noise of our images. The original fourteen fields consist of real radio emission on top of a background of Gaussian noise. During stacking, the noise in these fields goes down proportionally to the inverse square root of the number of stacks. The presence of real emission peaks in the residual field maps does not affect this, since these peaks are uncorrelated from stack to stack. In the upper panel of Figure 7, we show an example of the pixel distribution of one of our residual stacks, showing that it very nearly approximates a normal distribution, as indicated by the dashed black line, with $\sigma = {24.6}\, \mathrm{mK}$ . All our stacks exhibit this kind of normal distribution of pixel values, and so we will characterise them by reference to the standard deviation of their residual maps.

Figure 7. An example of the noise characteristics of the residual stack, in this case from the Max 15 Mpc stack. Top: The pixel distribution of the residual map, showing an approximately normal distribution. The dashed black line shows the Gaussian fit to the distribution, parameterised as $\sigma = {24.6}\, \mathrm{mK}$ . Bottom: The radially average autocorrelation of the residual stack, showing the autocorrelation as having a half width at half maximum (dotted black line) of 0.074.

The noise, however, is spatially correlated. In the original fields prior to stacking, this spatial correlation is on the scale of dirty beam. In the stacked images, however, this is not the case, since during stacking we rescale each LRG pair. To characterise the effective resolution of the stacked image we perform a radially averaged two-dimensional autocorrelation of the residual stack, and we present an example of this in the lower panel of Figure 7. We observe in this plot both an extended peak in this function, showing the spatial correlation of pixels persists in the stacked images, and also a slight depression showing the cumulative sidelobes of the stacked, dirty beams. We characterise the effective resolution by measuring the full width at half maximum (FWHM). In this case, the half width at half maximum of the autocorrelation is 0.074, corresponding to a FWHM value of the residual map of 0.105.

These two metrics—the standard deviation and the effective resolution—allow us to understand the significance of any potential signal in our stacks. Specifically, peaks of excess emission that deviate significantly from the measured map noise, or extended emission on scales greater than the effective resolution, are tell-tale markers that we are encountering signal that deviates from otherwise stochastic noise.

5. Results and discussion

5.1. Stacking results

In Figure 8, we present the stacked results for the Max 15 Mpc catalogue. This catalogue consists of 601 435 LRG pairs, allowing our stack to reach a noise of 25 mK, more than twice as deep as the 118.5 MHz stack in V2021. As can be seen in the upper left panel of Figure 8a, the peaks at $x = \pm 1$ are the dominant features, and have a mean value of 4 292 mK. The upper right panel in Figure 8a shows the same stacked image, only with the colour scale adjusted down so as to emphasise the noise. We now note the shallow depressions around each of the peaks, which are attributable to the dirty beam’s negative sidelobes. The LRG model is shown in the bottom left panel, and the bottom right panel in Figure 8a shows the residual stack, after model subtraction. The model construction methodology is surprisingly effective, leaving no trace either of the sharp peaks at $x = \pm 1$ , as well as removing the sidelobe depressions. There is no readily apparent excess emission in the residual image. In the top panel of Figure 8b, we compare the one-dimensional slice through $y = 0$ of both the mean stacked image (blue) and model (red). The stacked image and model are so similar that we scarcely observe any of the stacked plot. Note that the widths of the peaks are narrower than observed in V2021: the peaks here have a FWHM value of 0.11, and whilst this value is not given in V2021, their peaks appear visually much wider. These peaks will be in part a function of the instrumental dirty beam, however this is not sufficient to explain this discrepancy; we discuss this more in Subsection 5.3. In the second panel of Figure 8b, we show the one-dimensional $y = 0$ slice through the residual image, where we have renormalised the scale to the estimated map noise. There are no peaks in this residual exceeding $3 \sigma$ . In the third panel, we display the mean value in the range $y = \pm 0.2$ as a function of x, and renormalise based on the estimated map noise. The aim of this transverse mean is to bring out faint, wide signals that might be present along the intercluster stacks. For this LRG catalogue, we observe no peaks exceeding $3 \sigma$ . Finally, in the lower panel we display the longitudinal mean in the range $-0.95 < x < 0.95$ , as a function of y. For a faint signal that spans the length of the intercluster stack, we would expect this plot to show a peak at $y = 0$ , however we observe no statistically significant signal. We conclude there is no statistically significant excess emission along the bridge for the Max 15 Mpc stack.

Figure 8. The Max 15 Mpc stack, with mean LRG peaks of 4 292 mK, residual noise of 25 mK, and effective resolution of 0.11.

The stacked results for the Max 10 Mpc catalogue are shown in Figure 9. With just a quarter of the LRG pairs as the larger Max 15 Mpc catalogue, the estimated noise of this stack is higher at 51 mK, just a slight improvement on the stated noise in the 118.5 MHz stack in V2021. The peaks at $x = \pm 1$ are higher than the previous stacks, at 4 699 mK, which is a result of the catalogue sampling from a more local redshift space, whilst their widths have a similar FWHM of 0.12. Once again, however, the residual image and one-dimensional slices show no indication of statistically significant excess emission along the bridge.

Figure 9. The Max 10 Mpc stack, with mean LRG peaks of 4 699 mK, residual noise of 51 mK, and effective resolution of 0.12.

Likewise, the stacked results for the Max ${60}^\prime$ and LRG-V2021 catalogues, in Figures 10 and 11 respectively, also show no evidence of excess emission. The Max ${60}^\prime$ stack has a noise of 30 mK and a large effective resolution of 0.26 that is a result of reduced lower angular threshold and corresponding variation in scaling during stacking. Similarly, the peak width has increased to 0.23. This LRG catalogue also samples significantly deeper in redshift space than the others, with the result that the LRG peaks are diminished in comparison, with a mean value of 3 769 mK. One small $\sim\!2.85\sigma$ peak is visible in the one-dimensional profile at $x = -0.73$ , however its width matches the effective resolution, and similar peaks throughout the residual image suggest it is consistent with the noise. Meanwhile, the LRG-V2021 stack has a noise of 41 mK, approximately 30% lower than the equivalent 118.5 MHz stack in V2021. It has a peak in the longitudinal profile at $y = 0.14$ that reaches a significance of $3.04 \sigma$ , but otherwise shows no evidence of intercluster signal and certainly not the kind of large-scale, clearly evident excess emission as shown in V2021.

Figure 10. The Max ${60}^\prime$ stack, with mean LRG peaks of 3 769 mK, residual noise of 30 mK, and effective resolution of 0.26.

Figure 11. The LRG-V2021 stack, with mean LRG peaks of 4 540 mK, residual noise of 42 mK, and effective resolution of 0.09.

The analysis of each of our LRG catalogue stacks leaves us unable to corroborate the detection of V2021.

5.2. Sensitivity to extended emission

The chief distinction between the MWA Phase I and Phase II instruments is the location of the antennas, and in turn, each instrument’s respective dirty beam. As noted previously, the point-source sensitivity is unchanged. However, these modified baselines may make the instrument less sensitive to extended emission, potentially even resolving out large-scale emission such as the cosmic web, and this may be a factor in our non-detection.

In Figure 12 we show the dirty beams of the Phase I and Phase II instrument, as well as the effective dirty beam of the Phase II instrument after our convolution to ${3}^\prime$ (at zenith) resolution. These dirty beams have been generated from archival 118.5 MHz MWA observations at the centre of field 11 ( $\alpha = {180}^\circ$ , $\delta = {18}^\circ$ ) to best model the effect of the low-elevation pointings on the dirty beam. The Phase I dirty beam is produced with a Briggs –1 baseline weighting scheme such that it matches the original GLEAM imaging parameters, and has a resolution of approximately $3.74^\prime \times 2.56^\prime$ . Note the sizeable negative sidelobes around the beam, owing to a dense core of short baselines. The Phase II dirty beam is produced with the same baseline weighting as used in the present work, Briggs +1, as well as its lower baseline length threshold of $15 \lambda$ , and has a resolution of approximately $3.2^\prime \times 1.9^\prime$ . After convolution, this grows to a resolution of $4.2^\prime \times 3.1^\prime$ at the centre of the field.

Figure 12. A comparison of dirty beams used in V2021 and the present study, measured at 118.5 MHz and pointing $\alpha = {180}^\circ\delta = {18}^\circ$ . White dashed contours trace a response of zero, so as to better show the negative sidelobe regions. Left: The Phase I dirty beam with baseline weighting Briggs –1, as used in GLEAM, having a resolution of $3.74^\prime \times 2.56^\prime$ . Centre: The Phase II dirty beam with baseline weighting Briggs +1, as used in the current study, and having a resolution of $3.2^\prime \times 1.9^\prime$ . Right: The Phase II dirty beam, after convolution, having a resolution of $4.2^\prime \times 3.1^\prime$ .

Hodgson et al. (Reference Hodgson, Johnston-Hollitt, McKinley, Vernstrom and Vacca2020) developed an empirical method to measure an instrument’s sensitivity to large-scale emission, which we draw on here. Often angular sensitivity is estimated solely based on the angular size of the fringe patterns of the shortest baselines in an array, however, this does not take into account the imaging parameters, baseline weightings, and most importantly, the cumulative effect of the instrument’s baselines in determining angular sensitivity. Instead, the method we use here proceeds by simulating a range of extended emission sources—in our present case circular Gaussian sources—directly into the visibilities of an observation, and then producing a dirty image of the source. Given a surface flux density of $1\,\mathrm{Jy\, deg}^{-2}$ at the Gaussian peak, we can understand the instrument’s response by measuring the flux density at the centre of the Gaussian in the dirty image. If we iterate through many such circular Gaussian sources of increasing size, we will identify a threshold angular scale at which point the central response will begin to reduce, above which scales the dirty image of the Gaussian will start to ‘hollow out’ in the centre and become increasingly dark. In this way we can identify the relative sensitivity of the instrument over a range of angular scales as well as the angular scale at which emission begins to resolve out.

In Figure 13 we show the results of this exercise, where we have measured the central response to circular Gaussians having a FWHM up to ${180}^\prime$ in extent. It is immediately apparent that the larger beam size of the Phase I instrument makes it more sensitive than Phase II to large-scale emission features, as we’d expect. Moreover, the Phase I instrument does not begin to resolve out structure on these spatial scales; in fact, it continues to gain sensitivity over this range. The sensitivity of the Phase II instrument, on the other hand, begins to slowly decline on angular scales larger than ${30}^\prime$ , and then more rapidly decline on scales larger than approximately ${50}^\prime$ . The effect of convolving the Phase II dirty beam is dramatic, amplifying its sensitivity to extended sources more than a factor of two. Crucially, it also makes the instrument more sensitive than Phase I. It does not forestall the angular scales on which the instrument begins to resolve out structure, however it remains more sensitive than Phase I to extended emission out to approximately ${130}^\prime$ .

Figure 13. The sensitivity of Phase I, II, and Phase II (convolved) to extended emission. The plot shows the response at the centre of simulated circular Gaussians of varying sizes, with the simulated sources having a constant peak surface brightness of $1\,\mathrm{Jy\, deg}^{-2}$ . For large, extended emission sources, there exists a threshold angular scale above which the central response begins to drop, as these sources become increasingly ‘resolved out’. On the other hand, for very small angular sizes, the simulated source becomes smaller than the dirty beam (i.e. is unresolved) whilst maintaining the same peak surface brightness; the total flux of the source thus rapidly drops to zero as does the instrumental response.

When considering whether these differences in sensitivity to extended emission can account for our non-detection of the synchrotron cosmic web we need to understand the typical angular scales we would expect. In the first instance, the majority of LRG pairs in each catalogue are separated by less than ${60}^\prime$ , with the exception of the LRG-V2021 catalogue which has a median separation of ${79}^\prime$ . We should expect our observations to be at least as sensitive as V2021 for those LRG pairs with separations less than ${60}^\prime$ , and specifically with regards to the Max ${60}^\prime$ stack, there is no risk of resolving out structure across the entirety of its LRG pair catalogue. Secondly, we do not expect the emission spanning the intercluster region to be as wide as it is long: whilst our selection criteria allows for these bridges to span up to ${180}^\prime$ , we should expect the width of the bridge to be significantly more narrow. Any MWA baseline fringes aligned approximately along the narrower width will not be at risk of resolving out the emission, and this will reduce the overall effect. Finally, as simulations by Vazza et al. (Reference Vazza, Ettori, Roncarelli, Angelinelli, Brüggen and Gheller2019) and further showcased in Hodgson et al. (Reference Hodgson, Vazza, Johnston-Hollitt and McKinley2021b) have shown, the morphology of the cosmic web is expected to consist of radio-relic-like accretion shocks. These typically appear as long extended arcs of emission, usually with a well-defined edge along the shock itself, with many such shocks spanning the length of the intercluster region. Crucially, these kinds of emission mechanisms do not form a broad, continuous bridge of emission that we might risk resolving out, rather they are punctuated and individually consist of sharply defined edges that interferometers are well-suited to detect.

For these reasons, we do not believe we are adversely affected by the higher resolution MWA Phase II instrument.

5.3. The expected peak widths

As noted, a key difference between our results and those of V2021 is that the width of the peaks at $x = \{-1, 1\}$ of our stacks are much narrower. In this section, we want to understand the expected minimum size of these peaks. This condition of minimum peak width occurs when the angular scale of the LRG emission (or other spatially correlated emission) is much smaller than the instrumental dirty beam, that is, when the LRG emission is unresolved and approximately ‘point-like’. In this case, the instrumental response is simply the dirty beam itself. We can then model the expected minimum-width LRG peak profile by stacking the dirty beam in the following way: for each LRG pair, we calculate the angular distance between the pair and find a scaling factor to upscale onto the maximum angular separation, being ${3}^\circ$ ; we use this scaling factor to stretch the one-dimensional profile of the dirty beam; and then sum this alongside other similarly scaled profiles. We build in two additional assumptions in this simple model: first, for each pair we create a one-dimensional profile of the dirty beam at a uniformly random angle through the two-dimensional peak response, which assumes that the orientation of LRG pairs on the sky are approximately uniform; second, that each LRG has an equal contribution to the sum. A key limitation of this exercise is the use of a single dirty beam, as shown previously in Figure 12; these dirty beams have been generated for a fixed position on the sky, and at these low elevations the dirty beam is especially sensitive to the foreshortening effects of declination changes. Nonetheless, this exercise will give us a good approximation of the minimum peak sizes.

We show the results of this exercise in Figure 14 for both the Phase I (green) and Phase II (convolved; blue) dirty beams calculated across the Max 15 Mpc catalogue, as well as the model profile of the left peak of the Max 15 Mpc stack (red), shown previously in Figure 8. The FWHM of the Phase II (convolved) peak is 0.12, which compares to the actual model peak width of 0.11. The similarity in both the peak shape and width between this exercise and the actual model suggests the peaks in our stacks are dominated principally by unresolved sources.

Figure 14. One-dimensional profiles of stacked dirty beams for Phase I (green) and Phase II (convolved; blue), in comparison to the Max 15 Mpc stacked model profile (red). The stacked dirty beams approximate a minimum peak profile for purely unresolved LRG sources, and the similarity to the Max 15 Mpc stacked model profile suggests this profile is dominated principally by unresolved sources.

In comparison, the peak widths of the stacks in V2021 appear significantly wider. In Figure 14, we also show the results of the same exercise for the Phase I dirty beam, showing a remarkably similar peak width to our own. That the peaks of V2021 are markedly wider would suggest that a significant proportion of sources in their stacks appear as resolved at Phase I resolution. Moreover, the lack of a ‘stepped peak’, caused by the addition of a dominant unresolved population and a fainter resolved population, would suggest that the resolved population actually dominates in the V2021 stacks. This is a fundamental discrepancy with our own results, for which we do not currently have an explanation.

5.4. The effect of CLEANing

One point of difference between V2021 and the present study is the technique used to subtract bright point sources. V2021 used a wavelet decomposition technique, whereby image features on small angular scales were identified by imaging a limited range of wavelet scales. These small-scale image maps were searched for all pixels having values greater than $5 \sigma$ of the map noise, which were then subtracted from the original maps. This technique subtracted out the brightest pixels of point sources but left a residual ring around the sources at values lower than $5 \sigma$ . Only compact, point-like sources were subtracted from the images, thus leaving extended sources; it’s unclear what kind of additional filtering was applied to extended sources such as AGN lobes as this is not documented.

This differs with the present technique of using residuals after cleaning. Our cleaning process uses wsclean and its auto-mask and auto-threshold functionality. This worked by cleaning peaks of emission that are brighter than $3 \sigma$ , and when this was exhausted, cleaning was allowed to continue within a mask defined by the existing clean components down to a level of $1 \sigma$ . Recall that multiscale cleaning was disabled, and so this process removed peak emission that was greater than $3 \sigma$ ; large, diffuse extended emission that did not peak above this threshold remained in the image. In practice, typical snapshot noise was approximately ${20}\,\mathrm{mJy\, beam}^{-1}$ , meaning that peak emission fainter than approximately ${60}\,\mathrm{mJy\, beam}^{-1}$ was left in the images. Compare this to the $5 \sigma$ threshold used in V2021, which corresponds to approximately ${175}\,\mathrm{mJy\, beam}^{-1}$ . Thus there is significantly more emission remaining in the images of V2021.

For these point-source subtraction differences to contribute to the detection in V2021, this would imply that the excess emission arises from a population of especially bright sources that are visible in our own mosaics at levels of greater than ${60}\,\mathrm{mJy\, beam}^{-1}$ and which have been partially cleaned. Hodgson et al. (Reference Hodgson, Johnston-Hollitt, McKinley, Vernstrom and Vacca2020) showed that the luminosity of accretion shocks around the periphery of dark matter halos throughout their simulated cosmic web approximated a power law as a function of dark matter halo mass; in their ${15 \times 15}^\circ$ simulated field, there existed a few bright points of cosmic web emission, with the brightest at ${64}\,\mathrm{mJy\, beam}^{-1}$ (using a Phase I MWA beam). Note, however, that these sources were located around the periphery of bright clusters, not in the true intercluster region, that they were morphologically akin to radio relics, and were likely stationary accretion shocks around massive clusters. Only a handful of such bright, outlier emission sources were predicted as part of the simulation.

To investigate this further, as an exercise we have re-run the stacking process using the restored field images, rather than the residuals. To mitigate the effects of bright point-source emission, we have masked bright sources, but note that we have extended the threshold for this masking out to ${250}\,\mathrm{mJy\, beam}^{-1}$ . The motivation for this much higher threshold is to capture emission that is present in the original V2021 images, but which we have removed by our deeper cleaning. Figure 15 shows an example of one of these masked fields, where we can clearly see a large population of sub-250 mJy sources still present.

Figure 15. An example of masking the restored fields using a threshold of ${250}\,\mathrm{mJy\, beam}^{-1}$ , with masked sources depicted here as white. Note the presence of a low to medium brightness population of radio sources still clearly visible.

We show the stacked results of this exercise in Figure 16. Firstly, note that the mean residual value is much greater than zero. This results from the significant number emission sources present in the image when masking to only a threshold of ${250}\,\mathrm{mJy\, beam}^{-1}$ , and this non-zero background represents a kind of mean, stacked background temperature. Despite this, the peaks at $x = \{-1, 1\}$ have almost doubled against this background temperature, when compared with the Max 15 Mpc stack in Figure 8, showing that there is a considerable number of LRG sources (or sources otherwise correlated with the LRG population) with a peak brightness greater than approximately ${60}\,\mathrm{mJy\, beam}^{-1}$ . As a side-effect of the number of sources remaining in the image, however, the noise has also increased compared to the Max 15 Mpc stack, by a factor of just over 2.5 times at 62 mK. Note also the absence of the negative sidelobes about the LRG peaks. The extra emission of the LRG peaks compared to the original Max 15 Mpc stacks is the result of restored emission that has been convolved with an elliptical Gaussian fitted to the dirty beam, and this additional component will not have sidelobes; these brighter Gaussian sources in the stacks, combined with the overall higher noise, have washed out the subtle sidelobes of the fainter, uncleaned sources.

Figure 16. The Max 15 Mpc stack after masking fields at a threshold of ${250}\,\mathrm{mJy\, beam}^{-1}$ , with mean LRG peaks of 8 776 mK above the background, residual noise of 64 mK, and effective resolution of 0.12.

Figure 17. Original GLEAM survey images at 118.5 MHz, stacked using the Max 15 Mpc LRG catalogue, displaying mean LRG peaks of 4 600 mK, residual noise of 87 mK, and effective resolution of 0.16.

Turning now to the detection of excess emission, we can observe in Figure 16 that there is a peak of emission in the residual image centred at $(x, y) = ({-}0.57, 0.035)$ , slightly off the y-axis, and peaking at $4.58 \sigma$ significance. This peak corresponds to the peak in the one-dimensional profile also at $x = -0.57$ . The width of the peak is slightly extended beyond the FWHM typical of the rest of the residual image. A second, smaller peak is also evident in the residuals at $(x, y) = ({-}0.07, 0.13)$ with $4.2 \sigma$ significance, and is also visible in the transverse mean. Combined, these two peaks contribute to a peak in the longitudinal mean, at $y = 0.04$ with $3.2\sigma$ significance. Note also the presence of a $4.1 \sigma$ peak outside and to the left of the stacked intercluster region, at $(x, y) = ({-}1.85, 0.17)$ .

Are these emission peaks in the stacked residuals of Figure 16 evidence of the cosmic web? We can immediately note that these emission peaks have not reproduced the broad, excess emission of the kind in V2021 that filled the intercluster bridge; instead these are much more localised peaks. We can also note the asymmetry of the left peak at $x = -0.57$ , which is not reproduced on the right: this would suggest that this is not a generalised feature of the intercluster region. Additionally, the $4.1 \sigma$ peak to the left of the intercluster region cannot, by its location, be attributable to intercluster cosmic web emission. To investigate further, we have jackknife sampled the Max 15 Mpc catalogue, excluding a randomly selected 10% of the catalogue, and stacked each of the ten sub-catalogues. With 90% of the original catalogue in each stack, the noise is very similar, varying between 63–65 mK. We find that the peak at $x = -0.6 \pm 0.1$ is present in each stack, with at least a significance of $3.1 \sigma$ , with the exception of one of the sub-catalogues, where it is entirely consistent with the noise, and peaking at most at $2.4 \sigma$ . Similarly, the peaks at $x = -0.07$ and $x = -1.85$ are also each absent in one of the sub-catalogues. This exercise suggests that these peaks are not generalised features shared across the sample, but the effect of bright outlier emission left in the original fields.

This exercise suggests the absence of the broad excess emission feature found in V2021 in our own stacks is not a side-effect of cleaning.

5.5. Stacking the original GLEAM survey

We have every expectation that we should be able to detect the excess emission in our Phase II observations, given the low noise characteristics of our fields, our sensitivity to large-scale angular structures, and the additional LRG pairs that we have used in our stacks. It is still possible, however, that there is some aspect of these new observations or our image processing pipelines that has obscured or removed the synchrotron cosmic web. And so these concerns have led us to return to the original GLEAM survey data, and attempt to reproduce the results of V2021 by stacking an identical data set at 118.5 MHz.

To stack the GLEAM survey data, we first start with the full zenith equal area (ZEA) projection images at 118.5 MHz, which cover the right ascension regions spanned by our LRG pairs. Unlike V2021, we leave these images in their original projection. We mask bright points by selecting all emission regions with values greater than $5 \sigma$ of the local noise. To do this, we measure the spatially variable background—which is primarily the result of Galactic emission—as well as the noise using the Background and Noise Estimation tool (BANE; Hancock et al. Reference Hancock, Trott and Hurley-Walker2018). The mask is then created by subtracting out the background emission from the full projection, dividing by the noise image, and then masking all regions that exceed $5 \sigma$ of the local noise value. This process is substantially simpler than the wavelet subtraction method used in V2021, and the inclusion of the background subtraction step mitigates their stated concerns about masking. We additionally ‘grow’ all masked regions by 2 pixels, which we have found to be sufficient to avoid visually obvious rings of faint emission around the masks. Note that even after growing the masks slightly, this process leaves surrounding negative sidelobes about the masked regions, and this results in the remaining non-masked region having an overall negative mean. As with the previous masked stacks in Subsection 5.4, this will affect the ‘zero point’ of the final stacks. As previously, exclusion zones are identified around exceptionally bright sources, along sidelobe artefacts, and in one additional region where the background estimation had not been adequate due to a sharp change in the background brightness. Finally, the map is converted to temperature using the associated dirty beam map that described the major and minor axis variation of the beam. We then proceed to stack all LRG pairs from the Max 15 Mpc catalogue that overlap with the images, of which there are 645,950 unique pairs. All stacks are weighted by the inverse square of the local noise.

In Figure 17, we show the results of the GLEAM stacking with the Max 15 Mpc catalogue. This residual image is noticeably different from the one presented in V2021. In the first instance, there is no obvious, large-scale region of excess emission. In V2021, this excess region spanned the length of the intercluster region, and surprisingly was wider than it was long. The residual image is also highly uniform, again differing from V2021 where all the residual images, including the null tests, displayed a distinctive large-scale pattern. Curiously, the noise in this image is at 87 mK, which is higher than reported in V2021 even though we stack a much larger number of LRG pairs.Footnote e The one-dimensional profiles similarly display little evidence of excess emission in the residual, with the exception of a peak that reaches $3 \sigma$ in the integrated profile, at $x \approx -0.5$ , and which has a width very slightly wider than the effective resolution. There are at least 3 other peaks of similar magnitude and size throughout the residual image that cannot be attributed to intercluster cosmic web emission by reason of their location in the map, and so we must conclude that this peak is unexceptional.

Ultimately, we are unable to reproduce the broad and extended excess emission signal found in V2021, even when using the same data set, raising questions that these differences in results are due to the stacking procedure. In Appendix C, we perform a similar stacking procedure on the ROSAT broad X-ray data, as was performed in V2021. In this case, however, we detect a strong $12 \sigma$ signal for the Max 15 Mpc catalogue. This confirms the detection of V2021 for this data set, and provides us with confidence that our stacking and model subtraction processes will detect excess emission when it is present, and suggests that the discrepancy in results arises elsewhere in the analysis.

6. Conclusion

We have attempted to reproduce the detection of excess emission spanning LRG pairs in low-frequency radio data, as reported by V2021, and which they attributed to synchrotron emission along filaments spanning pairs of close-proximity clusters and galaxy groups. To reproduce their work, we have adhered very closely to their methodology: using the same LRG catalogue and selection criteria for pairs, stacking radio images at 118.5 MHz, and modelling the LRG and cluster contribution in the same way as V2021. We differ from V2021 primarily in that we use the upgraded MWA Phase II array, which has almost twice the resolution as the Phase I instrument used in V2021, and that our calibration, imaging and point-source subtraction pipelines utilised improved workflows that have been developed since the original GLEAM survey.

We have not been able to reproduce their result. Indeed, we have not been able to reproduce their result across a number of LRG pair catalogues, including the original abridged catalogue used in V2021, as well as a much larger catalogue that uses the full range of LRG pairs that meet the original selection criteria of V2021. We reach noise levels in our final stacks consistently lower than those of V2021, and more than twice as deep when using the full range of available LRG pairs. At these noise levels, their reported filamentary temperature should appear as approximately an $8 \sigma$ detection. Our residual stacks, however, are consistent with noise.

Our biggest concern with using MWA Phase II is the potential that we resolve out large, extended structures. However, we have shown that we are at least as sensitive to extended sources as Phase I out to $\sim\!{125}^\prime$ thanks to our extra convolution step, and that even for extended emission up to the maximum separation of ${180}^\prime$ , the likely shape and structure of this emission will reduce the effects of resolving out structure. Moreover, we have provided results of an additional LRG pair catalogue, with sources separated by ${15}-{60}^\prime$ , that mitigates these concerns; the stacking results of this catalogue reach noises lower than those of V2021 and yet still do not reproduce their observed excess emission.

In addition, we have returned to the original GLEAM survey data where we have performed stacking using the expanded Max 15 Mpc LRG pair catalogue. Whilst we do find an isolated peak at just above $3 \sigma$ significance, we find this to be an unremarkable feature of the residuals and certainly not the broad, extended excess emission as found in V2021. This non-detection is in spite of clearly reproducing the excess emission after stacking the ROSAT broad X-ray data, giving us good confidence in our stacking and modelling processes.

If our results hold true, we have provided in this work the strongest limits on synchrotron emission from intercluster filaments. However, the discrepancy with the work of V2021 is concerning and begs explanation. Whilst our Phase II results alone left open the possibility that this discrepancy arose due to a real, intrinsic property of the emission, our inability to reproduce the results additionally with GLEAM points to a much more likely possibility: that an error has been made in these detection attempts either by V2021 or ourselves. To this end, we are making publicly available the images of our fields, our stacking and modelling code, and the stacked images themselves, in the hope that if we have indeed erred, it can be quickly identified. Given the significance of the V2021 result, and the surprising implications on our understanding of cosmic magnetism, there is a pressing need reproduce their detection.

Acknowledgements

This scientific work makes use of the Murchison Radio-astronomy Observatory, operated by CSIRO. We acknowledge the Wajarri Yamatji people as the traditional owners of the Observatory site. Support for the operation of the MWA is provided by the Australian Government (NCRIS), under a contract to Curtin University administered by Astronomy Australia Limited. We acknowledge the Pawsey Supercomputing Centre which is supported by the Western Australian and Australian Governments. This work was supported by resources provided by the Pawsey Supercomputing Centre with funding from the Australian Government and the Government of Western Australia. We acknowledge the use of NASA’s SkyView facility (http://skyview.gsfc.nasa.gov) located at NASA Goddard Space Flight Center.

A. Synthetic stacks

To validate our stacking and modelling process, we have created a synthetic ‘cosmic web’ map and associated catalogue. We created a $14\,000 \times 14\,000$ pixel map, randomly positioned 26 000 point sources with peak temperature of 1 K and then selected pairs of peaks that were separated in the range ${20}-{180}^\prime$ . Pairs were randomly selected to produce a pair separation distribution that strongly favoured shorter separations, so as to approximate the distributions as seen in Figure 2; 5 539 pairs were chosen in this way. For each chosen pair, we drew a ‘filament’ as a straight, single pixel line, with each pixel having a value of 0.005 K. Finally, we convolved the image with the Phase II (convolved) beam, as shown in Figure 12. The resulting map is shown in Figure A1 where the point sources can be readily observed whilst the cosmic web filaments are not visually detectable above the sidelobe confusion, which is approximately 25 mK.

Figure A1. A zoom of the synthetic cosmic web image, showing randomly positioned 1 K point sources with a subset of pairs connected by faint ‘filaments’. After convolution to with the Phase II (convolved) beam, the filaments become hidden beneath the 25 mK sidelobe confusion noise.

In Figure A2 we show the results after stacking and model subtraction. The stacked point sources peak at approximately 1 K, in agreement with their injected values. Note also the presence of the faint, negative lobes about the exterior sweep of each peak, resulting from the negative lobes of the dirty beam. In practice, both the width of the peaks and positioning of the sidelobes are highly dependent on the distribution of the angular separation of pairs, which in turn affects the mix of rescaling that is required during stacking; for catalogues with more distant pairs, the peaks became narrower and the sidelobes less prominent. As can be seen in the residual image, after model subtraction we clearly recover the ‘cosmic web’ bridge. The model subtraction process does well to compensate for the negative sidelobes, resulting in a bridge that is fairly constant as can be seen in the one-dimensional profile, at approximately $11 \sigma$ in the residual along $y = 0$ . This is reduced in the transverse mean profile as a result of the narrowness of the filament, however the signal exceeds $30 \sigma$ in the longitudinal profile.

Figure A2. The synthetic stacks, with mean peaks of 1.02 K, residual noise of 1 mK, and effective resolution of 0.11.

We believe these results validate our stacking and modelling processes.

B. The weighting of the stacks

When stacking the LRG pairs from each field, we have weighted each pair by an estimate of the field noise. We have previously noted that these noise maps are spatially varying across a field, as a function of the primary beam attenuation, and that even across a single LRG pair the noise may be varying. What effect does this have on the final weighting of each stack?

In Figure B1 we show the associated stacked weight maps constructed as part of the Max 15 Mpc stack for different weighting configurations. From left to right: the default $\frac{1}{\sigma^2}$ noise-weighted maps with ad-hoc exclusion zones as detailed in Subsection 3.3, the same but with the ad-hoc exclusion zones ignored during stacking and left unmasked, and finally with a constant weighting and no ad-hoc exclusion zones. We also provide a one-dimensional profile for each map through $y = 0$ , where we observe that each weighted map differs primarily by the weighting directly between the LRG pair.

Figure B1. Stacked weight maps for the Max 15 Mpc catalogue, using a variety of weighting configurations. The weights are ultimately derived from the estimated noise maps of each field, which are spatially varying across the fields. The dominant effect seen here is the result of LRG pairs near the edge of the fields that produces the tapering effect towards the edges, with secondary effects caused by the ad-hoc exclusion zones and the convex geometry of the field perimeter. Left: The stacked weight map resulting from the default, noise-weighted stacking, also showing a one-dimensional profile through $y = 0$ in the lower panel. Centre: The stacked weight map using noise-weighted stacking but ad-hoc exclusion zones ignored during stacking and left unmasked. Right: The stacked weight maps using constant weight during stacking, and with ad-hoc exclusion zones ignored.

Each stacked weight map shares a bright central component that tapers off towards the edge. This is not an effect of local variation of noise in each field, but rather is a result of the convex perimeter of each field. During stacking, any LRG pairs near the edge of this field window have significant areas of their rescaled and rotated images ‘outside’ the field, and are therefore both set to zero and weighted as zero. The combined effect of this has resulted in the dominant tapering effect as observed. The secondary effect that we can observe in the stacked weight maps is the intercluster weighting, which varies from left to right as a shallow depression, shallow rise and a constant weight. There are two separate effects at work in creating these intercluster weightings. The first effect is the presence of the ad-hoc exclusion zones. Recall that the only requirement during stacking was that each LRG pair occupied a non-masked pixel, that is, that each LRG was interior to a field, and was not masked by an exclusion zone. This requirement did not, however, exclude cases where an ad-hoc exclusion zone existed between an LRG pair. This is the effect that dominates in the default example, causing the shallow depression in weighting between the LRG pair. If we ignore the ad-hoc exclusion zones during stacking, however, we instead obtain a stacked weight map with a slight rise in the intercluster region. This effect is caused by variations in local map noise caused by one special case: when stacking LRG pairs along the convex perimeter of the field. When stacking such pairs, the direct line between the LRG pair passes from the field perimeter towards the field interior, going from the maximum noise at the field edge towards a slightly reduced noise environment towards the interior. The effect of this is to slightly upweight the intercluster region. Finally, both of these effects are removed by considering the case of a constant weighted stack with no ad-hoc exclusion zones: we observe a constant weight between the LRG pair.

In practice, the weighting scheme has very little effect on the final stack. The constant weighted stack, which ignores both the local noise estimation and ad-hoc exclusion zones, has an estimated residual noise of 27 mK in comparison to the 25 mK of the noise-weighted stacks shown previously. Moreover, each of the three differently weighted stacks have visually identical residual maps.

Figure C1. The Max 15 Mpc stack of ROSAT broad images, with mean LRG peaks of $0.4238\, \mathrm{counts\, ks}^{-1}\, \mathrm{arcmin}^{-2}$ , residual noise of $0.9 \times 10^{-3}\, \mathrm{counts\, ks}^{-1}\, \mathrm{arcmin}^{-2}$ , and effective resolution of 0.05.

C. ROSAT stacks

V2021 performed stacking on X-ray data from ROSAT All-sky Survey (Voges et al. Reference Voges1999), and we reproduce this here using the ROSAT broad images $(0.1\text{--}2.4\, \mathrm{keV})$ . These images span further North than is possible with the MWA pointings, and so we are able to stack 757 731 LRG pairs as part of the Max 15 Mpc catalogue. The ROSAT broad data were downloaded as a series of ${20 \times 20}^\circ$ images in a gnomonic (TAN) projection, spanning the field of LRG pairs at intervals of ${10}^\circ$ on the sky. Bright pixels having a count greater than $20\, \mathrm{counts\, ks}^{-1}\, \mathrm{arcmin}^{-2}$ were blanked, but otherwise the images were not further processed.

The results of this stacking are shown in Figure C1. The residual image shows a large, excess region centred at $x = 0$ , but spanning the length of the intercluster region, and having a width approximately $-0.5 < y < 0.5$ . The excess signal is very well detected, having a one-dimensional profile that peaks just above $7 \sigma$ , corresponding to an excess value of $(6.6 \pm 0.9) \times 103\, \mathrm{counts\, ks}^{-1}\, \mathrm{arcmin}^{-2}$ , and an integrated profile (between $-0.2 < y < 0.2$ ) that peaks above $12 \sigma$ . A null test using unrelated LRG pairs ( $\Delta r > {150} \,\mathrm{Mpc}$ ) but otherwise conforming to the angular separation distribution of the Max 15 Mpc catalogue returned no excess signal. These excess values compare to the value found by V2021 of $(11.5 \pm 1.4) \times 10^{-3}\, \mathrm{counts}\, \mathrm{ks}^{-1}\, \mathrm{arcmin}^{-2}$ , although this value was found when stacking the abridged LRG-V2021 catalogue and was a mean across an unspecified ‘filamentary region’.

Note that the width of X-ray emission around each LRG peak is extremely broad. In fact, in the one-dimensional profile we can see the exterior sides do not become flat even out to $x = \{-3, +3\}$ . Indeed, this extreme width of each peak causes our model subtraction process to handle poorly. As we noted in Subsection 4.2, we independently model each LRG peak before simply adding each of their contributions. This works well when the contribution from each peak drops to zero for radial distances $r > 2$ . However, since in this case each peak still includes a non-negligible component present from the opposing peak, we therefore over-subtract, causing both the negative bowls of emission that can be seen in the residual image, as well as to underestimate the central excess emission.

Despite detecting a signal, we would hesitate to attribute this emission to true intercluster X-ray emission. The width of each peak implies that most of the emission in the centre of the residual images originates from cluster emission, and that a significant number of these pairs must overlap along our line of sight due to projection effects. It is therefore equally plausible that the excess emission in the centre originates due to asymmetric cluster emission, rather than hot intercluster filamentary gas. This is especially plausible given the number of clusters known to host substructures away from their core (Schuecker Reference Schuecker2005).

Footnotes

As noted in the addendum copy, there is an additional DOI for the dataset featured in this article: https://data-portal.hpc.swin.edu.au/dataset/searching-for-the-synchrotron-cosmic-web-again-a-replication-attempt.

a Murchison Widefield Array (MWA; Tingay et al. Reference Tingay2013).

c The local noise map is calculated using the median absolute deviation from the median (MADM) applied to a residual image that has not been primary beam corrected. We choose to use this image for our noise estimation as it has had bright sources removed and, prior to beam correction, the noise does not vary spatially, thus allowing for the easy calculation of a global value. We then apply a beam correction to this constant noise map so as to obtain an estimate of the local noise map, which varies spatially as a function of the primary beam.

d For the sake of reproducibility, these exclusion regions are included in the associated data release as DS9 region files.

e Note that the stated value in V2021 was calculated assuming the average noise in the original images reduced from stacking N LRG pairs as a factor of $1 / \sqrt{N}$, rather than being measured directly.

References

Baugh, C. M., et al. 2004, MNRAS, 351, L44Google Scholar
Brown, S. D. 2011, JApA, 32, 577Google Scholar
Brown, S., et al. 2017, MNRAS, 468, 4246Google Scholar
Cen, R., & Ostriker, J. P. 1999, ApJ, 514, 1Google Scholar
Davé, R., et al. 2001, ApJ, 552, 473Google Scholar
Eastwood, M. W., et al. 2018, AJ, 156, 32Google Scholar
Eckert, D., et al. 2015, Natur, 528, 105Google Scholar
Govoni, F., et al. 2019, Sci, 364, 981Google Scholar
Hancock, P. J., Trott, C. M., & Hurley-Walker, N. 2018, PASA, 35, e011Google Scholar
Hodgson, T., Johnston-Hollitt, M., McKinley, B., Vernstrom, T., & Vacca, V. 2020, PASA, 37, e032Google Scholar
Hodgson, T., Vazza, F., Johnston-Hollitt, M., Duchesne, S. W., & McKinley, B. 2021a, arXiv e-prints, p. arXiv:2108.13682Google Scholar
Hodgson, T., Vazza, F., Johnston-Hollitt, M., & McKinley, B., 2021b, PASA, 38, e047Google Scholar
Hoessel, J. G., Gunn, J. E., & Thuan, T. X. 1980, ApJ, 241, 486Google Scholar
Hoshino, H., et al. 2015, MNRAS, 452, 998Google Scholar
Hurley-Walker, N., & Hancock, P. J. 2018, A& C, 25, 94Google Scholar
Hurley-Walker, N., Seymour, N., Staveley-Smith, L., Johnston-Hollitt, M., Kapinska, A., & McKinley, B. 2017a, GaLactic and Extragalactic All-Sky MWA-eXtended (GLEAM-X) survey: Pilot observations, MWA Proposal id.2017A-11Google Scholar
Hurley-Walker, N., et al. 2017b, MNRAS, 464, 1146Google Scholar
Lopes, P. A. A. 2007, MNRAS, 380, 1608CrossRefGoogle Scholar
Macquart, J. P., et al. 2020, Natur, 581, 391Google Scholar
Nicastro, F., et al. 2018, Natur, 558, 406Google Scholar
O’Sullivan, S. P., et al. 2019, A&A, 622, A16Google Scholar
Offringa, A. R., et al. 2014, MNRAS, 444, 606Google Scholar
Piffaretti, R., Arnaud, M., Pratt, G. W., Pointecouteau, E., & Melin, J. B. 2011, A&A, 534, A109Google Scholar
Planck Collaboration, et al. 2016, A&A, 594, A27Google Scholar
Postman, M., & Lauer, T. R. 1995, ApJ, 440, 28Google Scholar
Pshirkov, M. S., Tinyakov, P. G., & Urban, F. R. 2016, PhRvL, 116, 191302Google Scholar
Sault, R. J., Teuben, P. J., & Wright, M. C. H. 1995, in Astronomical Society of the Pacific Conference Series, Vol. 77, Astronomical Data Analysis Software and Systems IV, ed. Shaw, R. A., Payne, H. E., & Hayes, J. J. E., 433 (arXiv:astro-ph/0612759)Google Scholar
Schneider, D. P., Gunn, J. E., & Hoessel, J. G. 1983, ApJ, 264, 337Google Scholar
Schuecker, P. 2005, RvMA, 18, 76Google Scholar
Sokolowski, M., et al. 2017, PASA, 34, e062Google Scholar
Tanimura, H., Aghanim, N., Douspis, M., Beelen, A., & Bonjean, V. 2019, A&A, 625, A67Google Scholar
Tanimura, H., et al. 2020, MNRAS, 491, 2318Google Scholar
Tingay, S. J., et al. 2013, PASA, 30, e007Google Scholar
Vacca, V., et al. 2018, MNRAS, 479, 776Google Scholar
Vazza, F., Ettori, S., Roncarelli, M., Angelinelli, M., Brüggen, M., & Gheller, C. 2019, A&A, 627, A5Google Scholar
Vazza, F., Ferrari, C., Brüggen, M., Bonafede, A., Gheller, C., & Wang, P. 2015, A&A, 580, A119CrossRefGoogle Scholar
Vernstrom, T., Gaensler, B. M., Brown, S., Lenc, E., & Norris, R. P. 2017, MNRAS, 467, 4914Google Scholar
Vernstrom, T., Gaensler, B. M., Rudnick, L., & Andernach, H. 2019, ApJ, 878, 92Google Scholar
Vernstrom, T., Heald, G., Vazza, F., Galvin, T. J., West, J. L., Locatelli, N., Fornengo, N., & Pinetti, E. 2021, MNRAS,Google Scholar
Voges, W., et al. 1999, A&A, 349, 389Google Scholar
Wayth, R. B., et al. 2015, PASA, 32, e025Google Scholar
Wayth, R. B., et al. 2018, PASA, 35, e033Google Scholar
Wen, Z. L., Han, J. L., & Yang, F. 2018, MNRAS, 475, 343Google Scholar
York, D. G., et al. 2000, AJ, 120, 1579Google Scholar
Figure 0

Figure 1. LRG pair distribution on the sky. The red points indicate pairs used in our stacks, whilst the grey are those pairs either outside our field or are within an exclusion zone.

Figure 1

Figure 2. The LRG pair distributions by redshift (left), angular separation (centre), and spatial separation (right), for each of the LRG pair catalogues used in our stacks.

Figure 2

Table 1. LRG pair statistics comparison between each of the LRG pair catalogues. We show the spatial and angular selection criteria for each catalogue, the number of LRG pairs that overlap with our fields (and the total pairs), their mean redshift, their mean angular separation, and their mean spatial separation, respectively. Spatial distances use a comoving metric.

Figure 3

Table 2. A summary of the 14 fields imaged, observed by the MWA Phase II instrument at 118 MHz. The fields span the right ascension range ${120}^\circ$ to ${240}^\circ$ in ${20}^\circ$ increments, at declinations of ${3}^\circ$ and ${18}^\circ$. We indicate the number of 112 s duration snapshots used in each field mosaic, and the resulting noise at the centre of the field. The model deviation describes the ratio of the measured flux density of sources after performing source finding, in comparison to the original calibration sky model; the $\mu$ term describes the mean values of these ratios, whilst $\sigma$ shows the standard deviation of these ratios.

Figure 4

Figure 3. Example calibration diagnostics for field 10, showing the declination correction. The 731 measured sources are compared to the calibration model. Prior to correction, their ratio has mean 0.044 dex and standard deviation 0.044 dex; after correction the mean becomes –0.001 dex and standard deviation 0.030 dex. Top: The measured to model flux density ratio, as a function of declination. The dashed line indicates the fit which is later used as an image-based correction. Centre: The distribution of measured to model flux density ratios for all 731 sources prior to (blue) and after (red) correction. Note in this case, the simple declination correction resolves the initial bimodal distribution. Bottom: The measured ratio of peak to integrated flux density, showing peak and integrated flux density of point sources are very nearly identical.

Figure 5

Figure 4. The central region of field 10, centred at RA ${160}^\circ$, Dec ${18}^\circ$, with ${3}^\prime$ resolution. Left: The full mosaic, with all clean components restored into the image. The peak flux density in this image is ${3.8}\,\mathrm{Jy\, beam}^{-1}$, whilst elsewhere in the field it is as high as ${34.6}\,\mathrm{Jy\, beam}^{-1}$. Right: The residual image, with all clean components subtracted out. This inset has a mean noise of ${7.5}\,\mathrm{mJy\, beam}^{-1}$, whilst the peak value is ${41}\,\mathrm{mJy\, beam}^{-1}$.

Figure 6

Figure 5. The maximum error associated with treating a SIN projection as a simple Cartesian grid, obtained at the maximum declination ${+32}^\circ$. Top: The maximum transverse error along a constant-declination ${180}^\prime$ line as a result of geodesics being curved in pixel space. Bottom: The maximum longitudinal error along a constant-hour-angle ${180}^\prime$ line, as a result of non-uniform pixel sizes.

Figure 7

Figure 6. An example showing the LRG model construction and subtraction from the stacked image, with all coordinates in the normalised coordinate system such that the LRG peaks are at $x = \{-1, 1\}$ and the y direction scales identically. Left: The original mean stacked image, with the dashed arcs indicating the exterior sweep over which each radially averaged one-dimensional model is constructed. The LRG peaks rise to just over 4 K; we have set the colour scale limits on these images to make the noise, at 24.6 mK, visible. Centre: The model sum map, produced by interpolating the one-dimensional model for each LRG peak onto the two-dimensional map. Right: The residual image, after subtracting the model from the original mean stack.

Figure 8

Figure 7. An example of the noise characteristics of the residual stack, in this case from the Max 15 Mpc stack. Top: The pixel distribution of the residual map, showing an approximately normal distribution. The dashed black line shows the Gaussian fit to the distribution, parameterised as $\sigma = {24.6}\, \mathrm{mK}$. Bottom: The radially average autocorrelation of the residual stack, showing the autocorrelation as having a half width at half maximum (dotted black line) of 0.074.

Figure 9

Figure 8. The Max 15 Mpc stack, with mean LRG peaks of 4 292 mK, residual noise of 25 mK, and effective resolution of 0.11.

Figure 10

Figure 9. The Max 10 Mpc stack, with mean LRG peaks of 4 699 mK, residual noise of 51 mK, and effective resolution of 0.12.

Figure 11

Figure 10. The Max ${60}^\prime$ stack, with mean LRG peaks of 3 769 mK, residual noise of 30 mK, and effective resolution of 0.26.

Figure 12

Figure 11. The LRG-V2021 stack, with mean LRG peaks of 4 540 mK, residual noise of 42 mK, and effective resolution of 0.09.

Figure 13

Figure 12. A comparison of dirty beams used in V2021 and the present study, measured at 118.5 MHz and pointing $\alpha = {180}^\circ\delta = {18}^\circ$. White dashed contours trace a response of zero, so as to better show the negative sidelobe regions. Left: The Phase I dirty beam with baseline weighting Briggs –1, as used in GLEAM, having a resolution of $3.74^\prime \times 2.56^\prime$. Centre: The Phase II dirty beam with baseline weighting Briggs +1, as used in the current study, and having a resolution of $3.2^\prime \times 1.9^\prime$. Right: The Phase II dirty beam, after convolution, having a resolution of $4.2^\prime \times 3.1^\prime$.

Figure 14

Figure 13. The sensitivity of Phase I, II, and Phase II (convolved) to extended emission. The plot shows the response at the centre of simulated circular Gaussians of varying sizes, with the simulated sources having a constant peak surface brightness of $1\,\mathrm{Jy\, deg}^{-2}$. For large, extended emission sources, there exists a threshold angular scale above which the central response begins to drop, as these sources become increasingly ‘resolved out’. On the other hand, for very small angular sizes, the simulated source becomes smaller than the dirty beam (i.e. is unresolved) whilst maintaining the same peak surface brightness; the total flux of the source thus rapidly drops to zero as does the instrumental response.

Figure 15

Figure 14. One-dimensional profiles of stacked dirty beams for Phase I (green) and Phase II (convolved; blue), in comparison to the Max 15 Mpc stacked model profile (red). The stacked dirty beams approximate a minimum peak profile for purely unresolved LRG sources, and the similarity to the Max 15 Mpc stacked model profile suggests this profile is dominated principally by unresolved sources.

Figure 16

Figure 15. An example of masking the restored fields using a threshold of ${250}\,\mathrm{mJy\, beam}^{-1}$, with masked sources depicted here as white. Note the presence of a low to medium brightness population of radio sources still clearly visible.

Figure 17

Figure 16. The Max 15 Mpc stack after masking fields at a threshold of ${250}\,\mathrm{mJy\, beam}^{-1}$, with mean LRG peaks of 8 776 mK above the background, residual noise of 64 mK, and effective resolution of 0.12.

Figure 18

Figure 17. Original GLEAM survey images at 118.5 MHz, stacked using the Max 15 Mpc LRG catalogue, displaying mean LRG peaks of 4 600 mK, residual noise of 87 mK, and effective resolution of 0.16.