Multi-instrument study of longitudinal wave structures for plasma bubble seeding in the equatorial ionosphere

IF 2.9 3区 地球科学 Earth and Planetary Physics Pub Date : 2021-10-22 DOI:10.26464/epp2021047
H. Takahashi, P. Essien, C. A. O. B. Figueiredo, C. M. Wrasse, D. Barros, M. A. Abdu, Y. Otsuka, K. Shiokawa, GuoZhu Li
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引用次数: 8

Abstract

Large Scale Wave Structures (LSWS) in the equatorial ionospheric F-region were observed by measuring spatial and temporal variations within detrended total electron content (dTEC) data obtained by ground-based GNSS receivers over the South American continent. By using dTEC-maps, we have been able to produce, for the first-time, two-dimensional representations of LSWS. During the period from September to December, the LSWS frequently occurred starting a few hours prior to Equatorial Plasma Bubble (EPB) development. From 17 events of LSWS observed in 2014 and 2015, wave characteristics were obtained: the observed wavelengths, periods, and the phase speeds are respectively, ~900 km, ~41 min and ~399 m/s; the waves propagated from the northeast to southeast. In some cases the front of the oscillation was meridionally aligned, extending to more than 1600 km, the first time such large extension of the wavefront has been reported. From F-layer bottom height oscillation data, measured by ionosonde, LSWS exhibit two different vertical phase propagation modes, in-phase and downward phase. The former mode indicates the presence of a polarization electric field in the F-layer bottom side; the latter suggests propagation of atmospheric gravity waves. The presence of LSWS near the solar terminator, followed by the development of EPBs, suggests that the upwelling of the F-layer bottom height produces a condition favorable to the development of Rayleigh–Taylor instability.

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赤道电离层等离子体气泡播种纵波结构的多仪器研究
通过测量南美大陆地面GNSS接收机获取的非趋势总电子含量(dTEC)数据的时空变化,观测了赤道电离层f区大尺度波结构(LSWS)。通过使用dtec -map,我们第一次能够生成LSWS的二维表示。在9月至12月期间,赤道等离子体泡(EPB)发展前几个小时开始出现LSWS。从2014年和2015年观测到的17个LSWS事件中,获得了波的特征:观测到的波长、周期和相速分别为~900 km、~41 min和~399 m/s;海浪从东北向东南传播。在某些情况下,振荡锋是经向对齐的,延伸超过1600公里,这是第一次报道如此大的波前延伸。从离子探空仪测得的f层底部高度振荡数据来看,LSWS呈现出同相和下相两种不同的垂直相位传播模式。前一种模式表明在f层底部存在极化电场;后者表明大气重力波的传播。在太阳终点附近出现的低场涡,以及随后出现的强场涡,表明f层底部高度的上升流为瑞利-泰勒不稳定的发展创造了有利条件。
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Earth and Planetary Physics
Earth and Planetary Physics GEOSCIENCES, MULTIDISCIPLINARY-
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17.20%
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