VHF Imaging Radar Observations and Theory of Banded Midlatitude Sporadic <i>E</i> Ionization Layers

Hysell, D. L.; Larsen, M. F.

doi:10.1029/2021ja029257

Cited by 7 publications

(12 citation statements)

References 56 publications

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“…The radar itself uses software‐defined signal synthesis and reception. Additional system hardware and software details and some preliminary observations were presented by Hysell and Larsen (2021).…”

Section: Data Presentationmentioning

confidence: 99%

“…In this article, we report on observations of 30-MHz coherent backscatter from patchy sporadic-E ionization layers (E s layers) obtained using a radar in Ithaca, New York, in the summer of 2021. This is a follow-on to the preliminary study presented by Hysell and Larsen (2021). The data set considered here is more extensive and includes 13 events observed between July and September 2021.…”

mentioning

confidence: 91%

“…In a series of papers, we have used such observations to analyze both the electrodynamics responsible for the plasma irregularities and the neutral shear instabilities and upwelling that drive the processes. The recent paper by Hysell and Larsen (2021) discusses coherent scatter data showing evidence for neutral shear instabilities of the Kelvin‐Helmholtz type and the evolution of secondary instabilities. References to earlier work can also be found in that article.…”

Section: Introductionmentioning

confidence: 99%

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Midlatitude Sporadic E‐Layer Horizontal Structuring Modulated by Neutral Instability and Mixing in the Lower Thermosphere

2023

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Observations of 30‐MHz coherent backscatter from sporadic‐E ionization layers were obtained with a VHF imaging radar located in Ithaca, New York. The volume probed by the radar lies at relatively high magnetic latitudes, on the northern edge of the mid‐latitude region and underneath the ionospheric trough. Banded, quasi‐periodic (QP) echoes observed from Ithaca are similar to those found in lower midlatitude regions. The Doppler shifts observed are smaller and, so far, do not appear to reach the threshold for Farley‐Buneman instability. However, many of the echoes exhibit fine‐scale structure, with secondary bands or braids oriented obliquely to the primary bands. Secondary bands have been seen only rarely at lower middle latitudes. In previous observations, the QP scattering has been linked to unstable neutral wind shears. Neutral wind shear commonly found in the lower thermosphere could play a key role in the formation of these irregularities and explain some morphological features of the resulting plasma density irregularities and the radar echoes. We consider whether neutral instability and turbulence in the lower thermosphere is the likely cause for some of the structuring in the sporadic‐ E layers. Results of 3D numerical simulations of atmospheric dynamics in the mesosphere to lower thermosphere support the proposition. In particular, we focus on Ekman‐type instabilities that, like the more common Kelvin‐Helmholtz instabilities, are inflection point instabilities, although specifically associated with turning shears, and result in convective rolls aligned close to the mean wind direction, with smaller‐scale secondary waves aligned normal to the primary structures.

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Section: Data Presentationmentioning

confidence: 99%

mentioning

confidence: 91%

Section: Introductionmentioning

confidence: 99%

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Midlatitude Sporadic E‐Layer Horizontal Structuring Modulated by Neutral Instability and Mixing in the Lower Thermosphere

2023

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“…In this work, the negative vorticity layer and the adjacent positive vorticity layer form a jet flow. The secondary vortices (Hysell and Larsen, 2021) are triggered in the strongly sheared braid regions. The secondary vortices roll up the stratification boundary layer with a higher velocity.…”

Section: The Structure Of the Es Layermentioning

confidence: 99%

“…The negative vorticity layers and the adjacent positive vorticity layers create a jet flow, as shown in the left panel (a) of Figure 6. The jet flow moves and amplifies along with the braids, leading to the generation of the secondary vortices (Hysell & Larsen, 2021) in the braid regions between the weakened primary KH vortices, as shown in the right panel (a) of Figure 6. The thin ion layers between the positive and negative vorticity layers converged, which leads to the accumulation of ions in the middle of the vortex region and the formation of the secondary vortex structure of ions in the braid regions, as shown in right panel (b) of Figure 6.…”

Section: The Small-scale Disordered Structure Coexists With the Kh Vo...mentioning

confidence: 99%

Simulation of Es Layer Modulated by Nonlinear Kelvin–Helmholtz Instability

Zhou

Wang

et al. 2022

JGR Space Physics

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In this study, a two‐dimensional numerical model of the nonlinear Kelvin–Helmholtz (KH) instability is used to investigate the nonlinear evolution processes of the ion layer, which is associated with the middle and low latitude E region irregularities. Based on simulation results, the two‐stage process in the evolution of the nonlinear KH instability is found in KH vortex morphology. The simulated nonlinear KH instability process presents multiple striation structures, including horizontal structures of the primary ion layer vortex with a size of a few kilometers and the secondary KH vortex with a size of 2 km. The polarization electric field is induced in the horizontal structure of the sporadic E (Es) layer associated with the vortex structure of neutral wind. The polarization electric field presents a similar tendency to the quasi‐periodic vortex structure. The horizontal distorted Es layer structure and anomalously large polarization electric field can provide the initial condition and lead to plasma instability, which can further develop to meter‐scale irregularities of QP echoes.

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Wind Shear Driven Double Layer Structures of E‐Region Irregularities at Low Latitudes

Liu,

Sun,

et al. 2024

Geophysical Research Letters

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Previous theoretical simulations showed the generation of double‐layer structures of E‐region field‐aligned irregularities (FAIs). In this study, we report the double‐layer structures of E‐region FAIs observed by an all‐sky radar at low latitude Ledong (18.4°N, 109°E), China. These FAIs appeared at the altitudes ∼90 and 110 km respectively. Both layers displayed quasi‐periodic patterns with synchronized spatial features, that is, being manifested as spatially separated patches or wavelike structures over similar longitudes at the two layers simultaneously. The neutral wind observations revealed the existence of wind shears at two separated altitudes where the double FAI layers occurred. The two wind shears created two vertically separated sporadic E layers and possibly drove the generation of the double‐layer FAIs via gradient drift instability. The synchronized spatial features of the FAIs at the two layers could be modulated by gravity waves.

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VHF Imaging Radar Observations and Theory of Banded Midlatitude Sporadic E Ionization Layers

Cited by 7 publications

References 56 publications

Midlatitude Sporadic E‐Layer Horizontal Structuring Modulated by Neutral Instability and Mixing in the Lower Thermosphere

Midlatitude Sporadic E‐Layer Horizontal Structuring Modulated by Neutral Instability and Mixing in the Lower Thermosphere

Simulation of Es Layer Modulated by Nonlinear Kelvin–Helmholtz Instability

Wind Shear Driven Double Layer Structures of E‐Region Irregularities at Low Latitudes

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