A LOFAR observation of ionospheric scintillation from two simultaneous travelling ionospheric disturbances

Fallows, R. A.; Forte, Biagio; Astin, Ivan; Allbrook, Tom; Arnold, Alex; Wood, Alan; Dorrian, Gareth; Mevius, M.; Rothkaehl, Hanna; Matyjasiak, Barbara; Krankowski, Andrzej; Anderson, J. M.; Asgekar, A.; Avruch, I. M.; Bentum, Mark J.; Bisi, M. M.; Butcher, H. R.; Ciardi, B.; Dąbrowski, Bartosz; Damstra, S.; Gasperin, F. de; Duscha, S.; Eislöffel, J.; Franzen, T. M. O.; Garrett, M. A.; Grießmeier, J.-M.; Gunst, A. W.; Hoeft, M.; Hörandel, J. R.; Iacobelli, M.; Intema, H. T.; Koopmans, L. V. E.; Maat, P.; Mann, G.; Nelles, A.; Paas, H.; Pandey, V. N.; Reich, W.; Rowlinson, A.; Ruiter, M.; Schwarz, Dominik J.; Serylak, M.; Shulevski, A.; Smirnov, O.; Soida, M.; Steinmetz, Matthias; Thoudam, Satyendra; Toribio, M. C.; Ardenne, A. van; Bemmel, I. M. van; Wiel, M. H. D. van der; Haarlem, M. P. van; Vermeulen, R. C.; Vocks, C.; Wijers, R. A. M. J.; Wucknitz, O.; Zarka, Philippe; Zucca, Pietro

doi:10.1051/swsc/2020010

Cited by 28 publications

(44 citation statements)

References 18 publications

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“…To analyse this constraint in more detail, we must first note that the scintillation zones are tens of degrees across in the sky, but as we will show below, the individual lensing plasma bubbles are much smaller. However, scintillation studies done with LOFAR by Fallows et al (2020) indicate that a fair approximation is that a scattering screen with turbulent cells moves past our line of sight rather faster than that it changes in its own rest frame, as in the case of interstellar scintillation. Therefore we will assume that the angular velocity we measure for the overall region also applies to the individual turbulent cells.…”

Section: Constraints From Strong Scintillation Zonesmentioning

confidence: 99%

“…In a recently published study of a strong scintillation episode in Cas A with LOFAR, Fallows et al (2020) perform a detailed analysis of dynamic spectra and of the time sequence in which the scintillation hits different LOFAR stations. They find that this episode is caused primarily by two layers of the ionosphere, the D region at around 80 km, where the plasma speed was about 110 m s −1 and the F region at 300-400 km altitude, where that speed was 20-40 m s −1 at the time.…”

Section: Constraints From Strong Scintillation Zonesmentioning

confidence: 99%

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Apparent radio transients mapping the near-Earth plasma environment

Kuiack

Wijers

Shulevski

et al. 2021

Monthly Notices of the Royal Astronomical Society

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We report the discovery of bright, fast, radio flashes lasting tens of seconds with the AARTFAAC high-cadence all-sky survey at 60 MHz. The vast majority of these coincide with known, bright radio sources that brighten by factors of up to 100 during such an event. We attribute them to magnification events induced by plasma near the Earth, most likely in the densest parts of the ionosphere. They can occur both in relative isolation, during otherwise quiescent ionospheric conditions, and in large clusters during more turbulent ionospheric conditions. Using a toy model, we show that the likely origin of the more extreme (up to a factor of 100 or so) magnification events likely originate in the region of peak electron density in the ionosphere, at an altitude of 300–400 km. Distinguishing these events from genuine astrophysical transients is imperative for future surveys searching for low frequency radio transient at time-scales below a minute.

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Section: Constraints From Strong Scintillation Zonesmentioning

confidence: 99%

Section: Constraints From Strong Scintillation Zonesmentioning

confidence: 99%

Apparent radio transients mapping the near-Earth plasma environment

Kuiack

Wijers

Shulevski

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…Rapid changes in ionospheric plasma density can significantly affect the performances of such instruments as the Low Frequency Array (LOFAR)-a European radio interferometer operating on a frequency range of 20-240 MHz [15]. Such sensitive instruments as LOFAR provide, also, some possibilities of ionospheric irregularity observations [16].…”

Section: Introductionmentioning

confidence: 99%

Climatology Characteristics of Ionospheric Irregularities Described with GNSS ROTI

et al. 2020

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At equatorial and high latitudes, the intense ionospheric irregularities and plasma density gradients can seriously affect the performances of radio communication and satellite-based navigation systems; that represents a challenging topic for the scientific and engineering communities and operational use of communication and navigation services. The GNSS-based ROTI (rate of TEC index) is one of the most widely used indices to monitor the occurrence and intensity of ionospheric irregularities. In this paper, we examined the long-term performance of the ROTI in terms of finding the climatological characteristics of TEC fluctuations. We considered the different scale temporal signatures and checked the general sensitivity to the solar and geomagnetic activity. We retrieved and analyzed long-term time-series of ROTI values for two chains of GNSS stations located in European and North-American regions. This analysis covers three full years of the 24th solar cycle, which represent different levels of solar activity and include periods of intense geomagnetic storms. The ionospheric irregularities’ geographical distribution, as derived from ROTI, shows a reasonable consistency to be found within the poleward/equatorward boundaries of the auroral oval specified by empirical models. During magnetic midnight and quiet-time conditions, the equatorward boundary of the ROTI-derived ionospheric irregularity zone was observed at 65–70∘ of north magnetic latitude, while for local noon conditions this boundary was more poleward at 75–85 magnetic latitude. The ionospheric irregularities of low-to-moderate intensity were found to occur within the auroral oval at all levels of geomagnetic activity and seasons. At moderate and high levels of solar activity, the intensities of ionospheric irregularities are larger during local winter conditions than for the local summer and polar day conditions. We found that ROTI displays a selective latitudinal sensitivity to the auroral electrojet activity—the strongest dependence (correlation R > 0.6–0.8) was observed within a narrow latitudinal range of 55–70∘N magnetic latitude, which corresponded to a band of the largest ROTI values within the auroral oval zone expanded equatorward during geomagnetic disturbances.

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“…Observations are therefore recommended during day-time hours, especially for the LOFAR-EoR project. Recently, Fallows et al (2020) with a combined analysis of Global Navigation Satellite System (GNSS), ionosondes and LOFAR reveals large-scale travelling ionospheric disturbances (TIDs) and small-scale TIDs travelling perpendicular to each other. These cause instabilities which breakdown large-scale structures into smaller scales during a weak sub-storm at high latitudes.…”

Section: Introductionmentioning

confidence: 99%

Study of the equatorial ionosphere using the Giant Metrewave Radio Telescope (GMRT) at sub-GHz frequencies

Mangla,

Datta

2022

Preprint

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Radio interferometers, which are designed to observe astrophysical objects in the universe, can also be used to study the Earth's ionosphere. Radio interferometers like the Giant Metrewave Radio Telescope (GMRT) detect variations in ionospheric total electron content (TEC) on a much wider spatial scale at a relatively higher sensitivity than traditional ionospheric probes like the Global Navigation Satellite System (GNSS). The hybrid configuration of the GMRT (compact core and extended arms) and its geographical location make this interferometer an excellent candidate to explore the sensitive regions between the northern crest of the Equatorial Ionization Anomaly (EIA) and the magnetic equator. For this work, a bright radio source, 3C68.2, is observed from post-midnight to post-sunrise (∼ 9 hours) to study the ionospheric activities at solar-minima. This study presents data reduction and processing techniques to measure differential TEC (𝛿TEC) between the set of antennas with an accuracy of 1 × 10 −3 TECU. Furthermore, using these 𝛿TEC measurements, we have demonstrated techniques to compute the TEC gradient over the full array and micro-scale variation in two-dimensional TEC gradient surface. These variations are well equipped to probe ionospheric plasma, especially during the night-time. Our study, for the first time, reports the capability of the GMRT to detect ionospheric activities. Our result validates, compared to previous studies with VLA, LOFAR and MWA, the ionosphere over the GMRT is more active, which is expected due to its location near the magnetic equator.

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A LOFAR observation of ionospheric scintillation from two simultaneous travelling ionospheric disturbances

Cited by 28 publications

References 18 publications

Apparent radio transients mapping the near-Earth plasma environment

Apparent radio transients mapping the near-Earth plasma environment

Climatology Characteristics of Ionospheric Irregularities Described with GNSS ROTI

Study of the equatorial ionosphere using the Giant Metrewave Radio Telescope (GMRT) at sub-GHz frequencies

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