Abstract
Using 630 nm airglow data observed by an airglow imager on the International Space Station (ISS), the occurrence of equatorial plasma bubbles (EPBs) is studied. In order to examine the physical mechanisms in the boundary region between the Earth and the outer space, an ionosphere, mesosphere, upper atmosphere, and plasmasphere mapping (IMAP) mission had been conducted onboard the ISS since October 2012. The visible light and infrared spectrum imager (VISI) is utilized in the ISS-IMAP mission for nadir-looking observation of the earth’s atmospheric airglow. In this study, we automatically select EPBs according to the criterion for extracting the tilted dark lines from VISI data. Using the selected events, the dependence of the occurrence rate of EPBs is examined. There is no other report of the occurrence rate of EPBs using downward-looking visible airglow data (630 nm). In this result, the occurrence rate is high at all longitudes in the equinoctial seasons. In the solstice seasons, in contrast, the occurrence rate is very small especially in the Pacific and American sectors. This result is basically consistent with previous studies, e.g., those determined by plasma density data on DMSP satellites.During the June solstice in 2013, EPBs were observed in association with geomagnetic storms that occurred due to a southward turning of the IMF Bz. Using these events, we examined the storm-time features of the occurrence of EPBs in the Pacific-American sectors during the June solstice. In these sectors, where the occurrence rate of EPBs is very small during solstice seasons, some EPBs were observed in the peak and recovery phases of the storms. This result shows that the prompt penetration of electric fields causes the development of EPBs, in the data we analyzed, the geomagnetic storms did not inhibit the generation of EPB in the Pacific–American sectors.
Highlights
In the age of satellite-based communication, the study of equatorial plasma bubbles (EPBs) becomes ever more important
We have shown that the occurrence rate of EPBs determined by the visible light and infrared spectrum imager (VISI) is similar to those determined by the Defense Meteorological Satellite Program (DMSP) satellites, the observation altitudes are different
In this study, the EPB occurrence is examined using nadirlooking 630 nm airglow data observed by the VISI imager on the International Space Station (ISS)-IMAP during 2013–2014
Summary
In the age of satellite-based communication, the study of equatorial plasma bubbles (EPBs) becomes ever more important. Defense Meteorological Satellite Program (DMSP) satellites track the sun-synchronous orbits at the altitude of 840 km and provide the in situ plasma density data. Burke et al (2004), followed by Gentile et al (2006), showed the seasonallongitudinal distributions of the occurrence rate of EPBs. Defense Meteorological Satellite Program (DMSP) satellites track the sun-synchronous orbits at the altitude of 840 km and provide the in situ plasma density data. Huang et al (2001) showed that the occurrence rate of EPBs is maximum in the equinoctial seasons, which is in general agreement with most ground-based observations. As for the solar activity dependence, it was clear that the occurrence rate increased with solar activity (e.g., Gentile et al (2006); Xiong et al (2010))
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