Abstract
Abstract. The ongoing Swarm satellite mission provides an opportunity for better knowledge of the near-Earth electromagnetic environment. Herein, we use a new methodological approach for the detection and classification of ultra low-frequency (ULF) wave events observed by Swarm based on an existing time-frequency analysis (TFA) tool and utilizing a state-of-the-art high-resolution magnetic field model and Swarm Level 2 products (i.e., field-aligned currents – FACs – and the Ionospheric Bubble Index – IBI). We present maps of the dependence of ULF wave power with magnetic latitude and magnetic local time (MLT) as well as geographic latitude and longitude from the three satellites at their different locations in low-Earth orbit (LEO) for a period spanning 2 years after the constellation's final configuration. We show that the inclusion of the Swarm single-spacecraft FAC product in our analysis eliminates all the wave activity at high altitudes, which is physically unrealistic. Moreover, we derive a Swarm orbit-by-orbit Pc3 wave (20–100 MHz) index for the topside ionosphere and compare its values with the corresponding variations of solar wind variables and geomagnetic activity indices. This is the first attempt, to our knowledge, to derive a ULF wave index from LEO satellite data. The technique can be potentially used to define a new Level 2 product from the mission, the Swarm ULF wave index, which would be suitable for space weather applications. Keywords. Space plasma physics (waves and instabilities)
Highlights
Swarm is the fourth Earth Explorer mission of the European Space Agency (ESA), launched on 23 November 2013
A number of magnetic and electric field missions flying in a low-Earth orbit (LEO), like CHAMP, Ørsted, SAC-C, or ST5, have enabled us to study in situ the occurrence of ultra lowfrequency (ULF) waves in the topside ionosphere
Our findings on Pc3 wave power distribution in magnetic and geographic coordinates based on 24 months of Swarm vector fluxgate magnetometer (VFM) observations (Figs. 5–6) confirm the results of a previous study on Pc3 wave power features in the topside ionosphere revealed by 1 year of Swarm absolute scalar magnetometer (ASM) observations (Balasis et al, 2015b)
Summary
Swarm is the fourth Earth Explorer mission of the European Space Agency (ESA), launched on 23 November 2013. A number of magnetic and electric field missions flying in a low-Earth orbit (LEO), like CHAMP, Ørsted, SAC-C, or ST5, have enabled us to study in situ the occurrence of ULF waves in the topside ionosphere. We present a new technique that combines a wavelet spectral analysis technique (Balasis et al, 2013), a state-of-the-art high-resolution magnetic field model (Finlay et al, 2016), and Swarm Level 2 products (i.e., fieldaligned currents – FAC – and the Ionospheric Bubble Index – IBI) in order to study the occurrence and distribution of compressional Pc3 waves in the topside ionosphere based on Swarm observations for a time period spanning 2 years.
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