Strong turbulent flow in the subauroral region in the Antarctic can deteriorate satellite-based navigation signals.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-01-27 DOI:10.1038/s41598-025-86960-6

D S Kotova, A A Sinevich, A A Chernyshov, D V Chugunin, Y Jin, W J Miloch

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引用次数: 0

Abstract

In the subauroral zone at the boundary of the auroral oval in the evening and night hours during geomagnetic disturbances, a narrow (about 1°-2°) and extended structure (several hours in longitude) is formed. It is known as a polarization jet (PJ) or the subauroral ion drift (SAID). The PJ/SAID is a fast westward ion drift and is one of the main signatures of a geomagnetic disturbance in the subauroral ionosphere at the altitudes of the F-layer, when the geomagnetic AE index reaches more than 500 nT. Plasma speed in the PJ/SAID can reach several kilometres per second, and the size of plasma irregularities inside it can reach scales from tens of meters to several hundred meters. Such high velocities and structured plasma can affect trans-ionospheric radio waves and lead to scintillations in the received signal. We show that at the moment of auroral activity intensification, an increase in the magnitude of phase scintillation index (σ_ϕ) as well as loss of satellite signals lock were observed in the region of the PJ/SAID equatorward of the auroral oval over Dronning Maud Land (Queen Maud Land) in Antarctica. We find that fluctuations inside the PJ/SAID can lead to serious deterioration of radio communication or navigational services. We emphasize the importance of considering the geometry of the beam passing from the GNSS satellite to the receiver on the ground. We highlight the mutual contribution of the PJ/SAID and the diffuse aurora boundary, which are almost impossible to separate in practice. Our results demonstrate the importance of considering the subauroral zone, where very dynamic plasma formations can occur with a strong flow and various-scale irregularities inside that lead to serious interference in satellite communications.

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南极副极光区的强湍流会削弱卫星导航信号。

在地磁扰动的傍晚和夜间时分，在极光椭圆边界的亚极光区，形成了一个狭窄的（约1°-2°）和延伸的（经度数小时）结构。它被称为偏振喷流（PJ）或亚极光离子漂移（SAID）。当地磁声发射指数达到500 nT以上时，PJ/SAID是一个快速向西漂移的离子，是亚极光电离层f层高度地磁扰动的主要标志之一。PJ/SAID内等离子体速度可达数公里/秒，其内部等离子体不规则大小可达数十米至数百米。如此高的速度和结构等离子体可以影响跨电离层无线电波，并导致接收信号中的闪烁。结果表明，在极光活动增强的时刻，在南极莫德女王地上空，极光椭圆方向的PJ/SAID赤道区域观测到相位闪烁指数（σ φ）的大小增加以及卫星信号锁定的丢失。我们发现PJ/SAID内部的波动会导致无线电通信或导航服务的严重恶化。我们强调考虑从GNSS卫星到地面接收器的波束几何形状的重要性。我们强调了PJ/SAID和漫射极光边界的相互作用，它们在实践中几乎是不可能分离的。我们的研究结果证明了考虑亚极光区的重要性，在亚极光区，非常动态的等离子体形成可能会发生强烈的流动和内部各种尺度的不规则性，从而导致卫星通信的严重干扰。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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