Global modeling of the low‐ and middle‐latitude ionospheric <i>D</i> and lower <i>E</i> regions and implications for HF radio wave absorption

Siskind, David E.; Zawdie, K.; Sassi, Fabrizio; Drob, Douglas P.; Friedrich, Martin

doi:10.1002/2016sw001546

Cited by 19 publications

(25 citation statements)

References 67 publications

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“…The Doppler flash feature can also be analyzed as arising from a change in conductivity of the ionosphere, which leads to a change in phase path of the EM wave. Another study done by Siskind et al (2017) showed that ionospheric absorption peaks at the lower E region and D region of the ionosphere where the ionization maximizes due to enhancement of X-ray and EUV flux. Clearly, the Doppler flash and D and E region absorption phenomenon are related and have similar driving processes.…”

Section: Discussionmentioning

confidence: 98%

Characterization of Short‐Wave Fadeout Seen in Daytime SuperDARN Ground Scatter Observations

et al. 2018

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Short‐wave fadeout (SWF) is a well‐known radio wave anomaly which follows Earth‐directed solar flares and leads to severe disruption of transionospheric high‐frequency systems. The disruption is produced by flare‐enhanced soft and hard X‐rays that penetrate to the D layer where they dramatically enhance ionization leading to heavy high‐frequency absorption over much of the dayside for an hour or more. In this paper, we describe how Super Dual Auroral Radar Network (SuperDARN) observations can be exploited to analyze SWF events. Superposed epoch analysis of multiple signatures reveals the typical characteristics of SWF. The number of SuperDARN ground scatter echoes drops suddenly (≈100 s) and sharply after a solar flare, reaching a maximum depth of suppression within a few tens of minutes, and then recovering to pre‐SWF conditions over half an hour or so. The depth of echo suppression depends on the solar zenith angle, radio wave frequency, and intensity of the flare. Furthermore, ground scatter echoes typically exhibit a sudden phase change leading to a dramatic increase in apparent Doppler velocity (the so‐called “Doppler flash”), which statistically precedes the dropout in ground scatter echoes. We report here on the characterization of SWF effects in SuperDARN ground scatter observations produced by several X class solar flares. We also describe the functional dependence of peak Doppler flash on solar zenith angle, frequency, and peak intensity of solar flux.

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Section: Discussionmentioning

confidence: 98%

Characterization of Short‐Wave Fadeout Seen in Daytime SuperDARN Ground Scatter Observations

et al. 2018

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“…Same as Figure but for midlatitude sounding rocket data taken from Wallops Island, VA. The rocket data are the five profiles listed in Table 1 of Siskind et al (). The VLF data (solid red up to the top of the waveguide; dashed extrapolation above) is taken from the height and steepness values given in Figure 6 of Thomson et al () for a solar zenith angle of 45° (i.e., β = 0.315 km −1 and

h^{'} = 74

km).…”

Section: Comparison Of Two Data Sets With Oasismentioning

confidence: 99%

“…Here we simply note that both the VLF community and the sounding rocket community are interested in the same atmospheric phenomena, which affect the D region. These can include solar variability (Danilov, ; Macotela et al, ; Mechtly, Bowhill, et al, ; Thomson et al, ), planetary waves (related to the winter anomaly discussed in the sounding rocket community; Beynon et al, ; Friedrich et al, ; Garcia et al, ; Pal et al, ; Siskind et al, ; Smith et al, ), and solar perturbations such as flares and eclipses (Bouderba et al, ; Chakraborty et al, ; Clilverd et al, ; Mechtly, Sechrist, et al, ; Mitra & Rowe, ; Singh et al, ). However, despite decades of work measuring the lower ionosphere by these techniques, with only a few exceptions, they typically are not intercompared.…”

Section: Introductionmentioning

confidence: 99%

“…Here we expand upon these initial comparisons to include theoretical calculations of the D region electron density profile as presented by Siskind, Martin, et al () and Siskind et al (; hereinafter referred to as S15 and S17) and the newer VLF data referred to above. We will also compare the HF (high frequency, 3‐30 MHz) absorption predicted by the electron densities inferred from the VLF reflection technique with previously published absorption calculations that relied upon rocket data.…”

Section: Introductionmentioning

confidence: 99%

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An Intercomparison of VLF and Sounding Rocket Techniques for Measuring the Daytime D Region Ionosphere: Theoretical Implications

et al. 2018

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We compare the two approaches that have been used to measure the lowermost ionosphere, the measurement of the propagation of very low frequency (VLF) radio waves and the in situ sampling by sounding rockets. We focus on the altitude, latitude, and zenith angle variation of the electron density profiles inferred from these two observational techniques as compared with a theoretical photochemical model. Our results show that below 68-70 km, the VLF data and the model agree better with each other than with the sounding rocket profile. At the lowest altitudes, near 60 km, both the VLF data and the model show a greater electron density at higher latitudes, consistent with a cosmic ray flux that increases with latitude, whereas the limited rocket data show a maximum at the tropics. Above 68-70 km, the VLF data and the sounding rockets agree better and at tropical latitudes, the model fails to reproduce the observations. Specifically, the calculated electron density is lower than the data by up to a factor of 2. Possible reasons for the model deficit include underestimates of the solar Lyman alpha flux, the solar X-ray flux and the mesospheric nitric oxide density. Once these three factors are mitigated, the model is in agreement with the observations between 60 and 80 km. Plain Language SummaryOver the past 50-60 years, there have been two approaches toward measuring the lowermost ionosphere (below 90 km), the D region. One is by modeling the propagation of VLF radio waves; the other is by in situ sampling via rockets. Until now, these techniques have not been rigorously intercompared. By comparing both with each other and with a theoretical photochemical model, we show how they are complementary. The very low frequency data are most accurate below 70 km, while the rocket data are more accurate above 70 km. The photochemical model can be made to agree with these data provided certain assumptions are made about the solar Lyman alpha flux, solar X-rays, and mesospheric nitric oxide (NO). Key Points: • We compare two independent techniques for measuring the D region ionosphere • Modeling VLF radio waves is most accurate below 70 km, in situ rockets are most accurate above 70 km • Photochemical model can agree with observations, but there are uncertainties concerning neutral atmosphere and solar flux inputs Supporting Information: • Supporting Information S1

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“…The variability in the ionosphere due to forcing from the stratosphere during a sudden stratospheric warming was more accurately reproduced by inclusion of realistic upward propagating GWs. Other examples of WACCM coupling to other models are described by Siskind et al () and Pedatella et al (). Further developments along these lines are being carried out, including assimilation of low‐altitude weather patterns, and validation with observations at low latitudes (McDonald et al, ).…”

Section: Innovative Techniquesmentioning

confidence: 99%

Ionospheric Detection of Explosive Events

Huang

Helmboldt

Park

et al. 2019

Reviews of Geophysics

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The ionospheric response to explosions which occur at or below the Earth's surface has been noted since the first detonations of nuclear devices during the early period of aboveground testing. Acoustic gravity waves and traveling ionospheric disturbances were detected in association with test explosions carried out by the Union of Soviet Socialist Republics in Novaya Zemlya in 1961. While research in this area has continued, the standards accepted by the Comprehensive Nuclear Test Ban Treaty for detection and confirmation of nuclear explosions have been based on (1) seismic, (2) hydroacoustic, (3) infrasound, and (4) radionuclide monitoring from ground detectors. We suggest that ionospheric sensing offers a complementary methodology that may allow for robust confirmation of explosive events. One method of ionospheric monitoring of explosive events is analysis of total electron content (TEC), available by processing data from Global Navigation Satellite System (GNSS) receivers distributed globally on land masses. Traveling ionospheric disturbances observed by their signature in TEC have been used to detect and confirm mine collapses, mine blasts, earthquakes, volcanic eruptions, and meteorite strikes as well as underground nuclear tests. While an integrated measurement like TEC is not as sensitive to small-amplitude density perturbations as other methods, the existence of large networks of continuously operating GNSS stations makes this an intriguing new monitoring asset. We report on the current capabilities for detection of explosions via the ionosphere, the outstanding challenges, and prospects for future developments that have potential to augment the current standards for detection and confirmation of nuclear detonations. By leveraging the worldwide network of GNSS receivers, robust confirmation of impulsive events is possible. This methodology complements existing technologies approved by the Comprehensive Test Ban Treaty. The article outlines background theory, new approaches to monitoring of explosions, and challenges that remain to be addressed.

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Global modeling of the low‐ and middle‐latitude ionospheric D and lower E regions and implications for HF radio wave absorption

Cited by 19 publications

References 67 publications

Characterization of Short‐Wave Fadeout Seen in Daytime SuperDARN Ground Scatter Observations

Characterization of Short‐Wave Fadeout Seen in Daytime SuperDARN Ground Scatter Observations

An Intercomparison of VLF and Sounding Rocket Techniques for Measuring the Daytime D Region Ionosphere: Theoretical Implications

Ionospheric Detection of Explosive Events

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