A new angle for probing field‐aligned irregularities with the Murchison Widefield Array

Loi, Shyeh Tjing; Murphy, Tara; Cairns, Iver H.; Trott, Cathryn M.; Hurley‐Walker, N.; Lü, Feng; Hancock, P. J.; Kaplan, David L.

doi:10.1002/2015rs005878

Cited by 6 publications

(5 citation statements)

References 102 publications

(177 reference statements)

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“…Also, the position offsets due to ionospheric refraction are inversely proportional to f 2 (e.g. Loi et al 2015), where f is the observing frequency. This implies that low-frequency radio waves will be affected more than high frequencies and also provides a quantitative scaling that should hold for ionospheric propagation effects.…”

Section: Excluding Other Systematic Effects For the Fine-scale Motionmentioning

confidence: 99%

Imaging-spectroscopy of a band-split type II solar radio burst with the Murchison Widefield Array

Bhunia

Carley

Oberoi

et al. 2023

A&A

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Type II solar radio bursts are caused by magnetohydrodynamic (MHD) shocks driven by solar eruptive events such as coronal mass ejections (CMEs). Often, both fundamental and harmonic bands of type II bursts are split into sub-bands, which are generally believed to be coming from upstream and downstream regions of the shock; however, this explanation remains unconfirmed. Here, we present combined results from imaging analyses of type II radio burst band splitting and other fine structures observed by the Murchison Widefield Array (MWA) and extreme ultraviolet observations from Solar Dynamics Observatory (SDO)/Atmospheric Imaging Assembly (AIA) on 28 September 2014. The MWA provides imaging-spectroscopy in the range 80−300 MHz with a time resolution of 0.5 s and frequency resolution of 40 kHz. Our analysis shows that the burst was caused by a piston-driven shock with a driver speed of ∼112 km s−1 and shock speed of ∼580 km s−1. We provide rare evidence that band splitting is caused by emission from multiple parts of the shock (as opposed to the upstream–downstream hypothesis). We also examine the small-scale motion of type II fine structure radio sources in MWA images, and suggest that this motion may arise because of radio propagation effects from coronal turbulence, and is not due to the physical motion of the shock location. We present a novel technique that uses imaging spectroscopy to directly determine the effective length scale of turbulent density perturbations, which is found to be 1−2 Mm. The study of the systematic and small-scale motion of fine structures may therefore provide a measure of turbulence in different regions of the shock and corona.

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Section: Excluding Other Systematic Effects For the Fine-scale Motionmentioning

confidence: 99%

Imaging-spectroscopy of a band-split type II solar radio burst with the Murchison Widefield Array

Bhunia

Carley

Oberoi

et al. 2023

A&A

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“…The existence of the ionosphere impacts lowfrequency radio observations in many ways. In fact, many interferometers that were designed for cosmology have turned out to be excellent instruments for ionospheric studies (e.g., Loi et al 2015aLoi et al , 2015bLoi et al , 2016Mevius et al 2016)!…”

Section: Ionospherementioning

confidence: 99%

Data Analysis for Precision 21 cm Cosmology

Liu

Shaw

2020

PASP

176

103

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The redshifted 21 cm line is an emerging tool in cosmology, in principle permitting three-dimensional surveys of our Universe that reach unprecedentedly large volumes, previously inaccessible length scales, and hitherto unexplored epochs of our cosmic timeline. Large radio telescopes have been constructed for this purpose, and in recent years there has been considerable progress in transforming 21 cm cosmology from a field of considerable theoretical promise to one of observational reality. Increasingly, practitioners in the field are coming to the realization that the success of observational 21 cm cosmology will hinge on software algorithms and analysis pipelines just as much as it does on careful hardware design and telescope construction. This review provides a pedagogical introduction to stateof-the-art ideas in 21 cm data analysis, covering a wide variety of steps in a typical analysis pipeline, from calibration to foreground subtraction to mapmaking to power spectrum estimation to parameter estimation.∆ 2 (k) [(mK) 2 ] z = 10, x HI = 0.878 z = 9, x HI = 0.776 z = 8, x HI = 0.595 z = 7, x HI = 0.283 z = 6, x HI = 0.004

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“…A typical radio image has a PSF which is equal to the synthesised beam, and which is constant across the field of view. At frequencies below ∼150 MHz, the ionosphere can induce a lensing effect which can decouple the PSF from the synthesised beam in a manner similar to seeing in optical images (as seen by Loi et al 2016). Additionally, stacking or mosaicking of images which are taken under different ionospheric conditions can introduce a blurring effect, due to uncorrected ionospheric shifts (as seen by Hurley-Walker et al 2017).…”

Section: Variable Point Spread Functionmentioning

confidence: 99%

Source Finding in the Era of the SKA (Precursors): Aegean 2.0

Hancock

Trott

Hurley‐Walker

2018

Publ. Astron. Soc. Aust.

Self Cite

186

174

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In the era of the SKA precursors, telescopes are producing deeper, larger images of the sky on increasingly small time-scales. The greater size and volume of images place an increased demand on the software that we use to create catalogues, and so our source finding algorithms need to evolve accordingly. In this paper we discuss some of the logistical and technical challenges that result from the increased size and volume of images that are to be analysed, and demonstrate how the Aegean source finding package has evolved to address these challenges. In particular we address the issues of source finding on spatially correlated data, and on images in which the background, noise, and point spread function, vary across the sky. We also introduce the concept of forced or priorized fitting.

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A new angle for probing field‐aligned irregularities with the Murchison Widefield Array

Cited by 6 publications

References 102 publications

Imaging-spectroscopy of a band-split type II solar radio burst with the Murchison Widefield Array

Imaging-spectroscopy of a band-split type II solar radio burst with the Murchison Widefield Array

Data Analysis for Precision 21 cm Cosmology

Source Finding in the Era of the SKA (Precursors): Aegean 2.0

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