Abstract
Abstract. Although positive and negative signatures of ionospheric storms have been reported many times, global characteristics such as the time of occurrence, time delay and duration as well as their relations to the intensity of the ionospheric storms have not received enough attention. The 10 years of global ionosphere maps (GIMs) of total electron content (TEC) retrieved at Jet Propulsion Laboratory (JPL) were used to conduct a statistical study of the time delay of the ionospheric responses to geomagnetic disturbances. Our results show that the time delays between geomagnetic disturbances and TEC responses depend on season, magnetic local time and magnetic latitude. In the summer hemisphere at mid- and high latitudes, the negative storm effects can propagate to the low latitudes at post-midnight to the morning sector with a time delay of 4–7 h. As the earth rotates to the sunlight, negative phase retreats to higher latitudes and starts to extend to the lower latitude toward midnight sector. In the winter hemisphere during the daytime and after sunset at mid- and low latitudes, the negative phase appearance time is delayed from 1–10 h depending on the local time, latitude and storm intensity compared to the same area in the summer hemisphere. The quick response of positive phase can be observed at the auroral area in the night-side of the winter hemisphere. At the low latitudes during the dawn-noon sector, the ionospheric negative phase responses quickly with time delays of 5–7 h in both equinoctial and solsticial months. Our results also manifest that there is a positive correlation between the intensity of geomagnetic disturbances and the time duration of both the positive phase and negative phase. The durations of both negative phase and positive phase have clear latitudinal, seasonal and magnetic local time (MLT) dependence. In the winter hemisphere, long durations for the positive phase are 8–11 h and 12–14 h during the daytime at middle and high latitudes for 20≤Ap<40 and Ap≥40.
Highlights
Geomagnetic storms have profound influences on the ionosphere, leading to disturbances in the ionospheric F2 region
During geomagnetic storms the enhanced magnetospheric energy and energetic particles input into the polar upper atmosphere greatly modify the dynamic and chemical coupling processes of the thermosphere and ionosphere system, resulting in significant changes in electron density profile and total electron content (TEC) derived from global positioning system (GPS) network measurements
And in subsequent figures we combine the results for the winter and summer seasons by reversing geomagnetic latitude, omitting the difference in the same seasons as observed in different hemispheres and taking the average value of the time delay
Summary
Geomagnetic storms have profound influences on the ionosphere, leading to disturbances in the ionospheric F2 region. Several mechanisms have been considered as possible sources for the ionospheric positive phases (e.g., Danilov and Belik, 1992; Prolss, 1995), the F2-layer uplifting due to vertical drift, plasma fluxes from the plasmasphere and downwelling to the gas as a result of the storm-induced thermospheric circulation (Danilov and Lastovicka, 2001). The altered thermospheric circulation causes downwelling of the neutral species through constant pressure surfaces at low–middle latitudes equatorward of the composition disturbance zone, increasing the O density relative to N2 and O2. This produces increases in NmF2 and TEC (Fuller-Rowell et al, 1996)
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