Browsing by Author "Drexler, J."

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    Combined radar observations of equatorial electrojet irregularities at Jicamarca
    (European Geosciences Union (EGU), 2007-03-08) Hysell, D. L; Drexler, J.; Shume, E. B; Chau Chong Shing, Jorge Luis; Scipión, Danny; Vlasov, M.; Cuevas, R.; Heinselman, C.
    Daytime equatorial electrojet plasma irregularities were investigated using five distinct radar diagnostics at Jicamarca including range-time-intensity (RTI) mapping, Faraday rotation, radar imaging, oblique scattering, and multiple-frequency scattering using the new AMISR prototype UHF radar. Data suggest the existence of plasma density striations separated by 3–5 km and propagating slowly downward. The striations may be caused by neutral atmospheric turbulence, and a possible scenario for their formation is discussed. The Doppler shifts of type 1 echoes observed at VHF and UHF frequencies are compared and interpreted in light of a model of Farley Buneman waves based on kinetic ions and fluid electrons with thermal effects included. Finally, the up-down and east-west asymmetries evident in the radar observations are described and quantified.
    Palabras clave:IonosphereEquatorial ionosphereIonospheric irregularities
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    Polarization of elliptic E region plasma irregularities and implications for coherent radar backscatter from Farley‐Buneman waves
    (American Geophysical Union, 2006-08-12) Hysell, D. L.; Drexler, J.
    The problem of two‐dimensional, homogeneous, elliptical irregularities in an otherwise homogeneous plasma with anisotropic conductivity is considered. We find an analytic solution for the potential inside and outside the irregularities. In the special case of circular irregularities, the internal electric field is reduced from the background field in both depletions and enhancements. The internal field is rotated in different directions for depletion and enhancements, however. When the irregularity is elongated, the electric field inside can be larger or smaller than the background field in both depletions and enhancements, depending on the attack angle of the background field. The effects of ion inertia can further suppress the internal electric field in small‐scale circular irregularities. These electrodynamics considerations may help explain some aspects of radar observations of irregularities excited by Farley‐Buneman waves and instabilities in the electrojets, in particular, their tendency to exhibit Doppler shifts significantly smaller than the line‐of‐sight background electron convection speed and proportional to the cosine of the flow angle. The analysis generalizes that of St.‐Maurice and Hamza (2001), who introduced this avenue of investigation.
    Palabras clave:Farley‐BunemanIrregularitiesElectrodynamics