支持空间气象服务的一种新的气候电子密度模型

IF 3.4 2区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
M. Mainul Hoque, N. Jakowski, F. Prol
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引用次数: 10

摘要

电离层是地球大气的电离部分,范围从大约60公里到几个地球半径,而高度超过1000公里到等离子层顶的上层通常被称为等离子层。我们提出了一个新的三维电子密度模型,旨在支持空间气象服务和减轻跨电离层信号的传播误差。该模型是将Neustrelitz等离子体层模型(NPSM)与由F层和e层分布组成的电离层模型叠加而成的。它使用Neustrelitz TEC模型(NTCM)、Neustrelitz峰密度模型(NPDM)和Neustrelitz峰高模型(NPHM)来获取总电子含量(TEC)、峰电离和峰高信息。这些模式描述了关键参数随当地时间、地理/地磁位置、太阳辐照和活动的时空变化。该模型专门用于计算电离层中任何给定位置和时间的电子浓度,用于跨电离层应用,并被命名为Neustrelitz电子密度模型(NEDM2020)。对DMSP和Swarm、Van Allen探测器和ICON任务的电子密度原位数据、COSMIC/FORMOSAT-3任务的上层TEC数据、TOPEX/Poseidon任务的底层TEC数据以及国际GNSS服务(IGS)的地面TEC数据进行了综合验证研究,涵盖了太阳活动的高和低条件。并与三维电子密度模型NeQuick2进行了性能比较。我们的研究表明,与范艾伦探测器和ICON卫星的原位数据以及COSMIC和TOPEX/Poseidon任务的TEC数据相比,NEDM2020的性能优于NeQuick2。与DMSP和IGS TEC数据相比,NEDM2020和NeQuick2的性能非常相似。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A new climatological electron density model for supporting space weather services
The ionosphere is the ionized part of the Earth atmosphere, ranging from about 60 km up to several Earth radii whereas the upper part above about 1000 km height up to the plasmapause is usually called the plasmasphere. We present a new three-dimensional electron density model aiming for supporting space weather services and mitigation of propagation errors for trans-ionospheric signals. The model is developed by superposing the Neustrelitz Plasmasphere Model (NPSM) to an ionosphere model composed of separate F and E-layer distributions. It uses the Neustrelitz TEC model (NTCM), Neustrelitz Peak Density Model (NPDM) and the Neustrelitz Peak Height Model (NPHM) for the total electron content (TEC), peak ionization and peak height information. These models describe the spatial and temporal variability of the key parameters as function of local time, geographic/geomagnetic location, solar irradiation and activity. The model is particularly developed to calculate the electron concentration at any given location and time in the ionosphere for trans-ionospheric applications and named as the Neustrelitz Electron Density Model (NEDM2020). A comprehensive validation study is conducted against electron density in-situ data from DMSP and Swarm, Van Allen Probes and ICON missions, and topside TEC data from COSMIC/FORMOSAT-3 mission, bottom side TEC data from TOPEX/Poseidon mission and ground-based TEC data from International GNSS Service (IGS) covering both high and low solar activity conditions. Additionally, the model performance is compared with the 3D electron density model NeQuick2. Our investigation shows that the NEDM2020 performs better than the NeQuick2 when compared with the in-situ data from Van Allen Probes and ICON satellites and TEC data from COSMIC and TOPEX/Poseidon missions. When compared with DMSP and IGS TEC data both NEDM2020 and NeQuick2 perform very similarly.
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来源期刊
Journal of Space Weather and Space Climate
Journal of Space Weather and Space Climate ASTRONOMY & ASTROPHYSICS-GEOCHEMISTRY & GEOPHYSICS
CiteScore
6.90
自引率
6.10%
发文量
40
审稿时长
8 weeks
期刊介绍: The Journal of Space Weather and Space Climate (SWSC) is an international multi-disciplinary and interdisciplinary peer-reviewed open access journal which publishes papers on all aspects of space weather and space climate from a broad range of scientific and technical fields including solar physics, space plasma physics, aeronomy, planetology, radio science, geophysics, biology, medicine, astronautics, aeronautics, electrical engineering, meteorology, climatology, mathematics, economy, informatics.
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