The Effects of the Recurrent Storms on Fof2 at Ouagadougou Station during Solar Cycles 21-22 ()
1. Introduction
An interaction between magnetized plasma propagating from the Sun and magnetic fields in the near-Earth space environment causes a global magnetic disturbance namely geomagnetic storms [1] which are due to geomagnetic activities.
Legrand and Simon [2] studied and classified the geomagnetic activity by using 1) the geomagnetic aa index carried out by Mayaud [3] [4] , 2) the date of Sudden Storm Commencement (SSC) and 3) the correlation existing between the geomagnetic aa index and the solar wind speed established by Svalgaard [5]. Their four classes are: 1) quiet magnetic activity due to slow solar wind; 2) recurrent activity related to high speed solar wind streams coming from coronal holes; 3) shock events with SSC caused by Coronal Mass Ejections (CMEs) and 4) fluctuating activity due to the fluctuation of the solar neutral sheet. Richardson and Cane [6] also found the same number of the geomagnetic classes. But they named the fluctuating activity as the unclear activity which characterized the cases where the solar mechanisms cannot be clearly identified.
It is well known that the F layer depends on: 1) the sunspot cycle [7] [8] ; 2) the Sun-Earth relative position at the origin of the seasonal variation and equinoctial maxima [9] [10] ; 3) the solar wind speed [11] [12] and the shock activity [13].
The statistical study of the foF2 diurnal variation at Ouagadougou station (Lat: 12.4˚N; Long: 358.5˚E; dip: 1.43˚) has been carried for the all geomagnetic activities [14]. Here, we focus our attention to a careful investigation on the F2 layer critical frequency (foF2) time variation at the same station when occurs the recurrent activity. This research is made after that of Gyébré et al. [15] which treated the different types of the shock activity impacts on foF2 time variation. The novelty of this study appears as it is a first paper where such statistical study is made. It is important to note that Rodríguez-Zuluaga et al. [16] also investigated the impact of this type of activity in the lower ionosphere but focus their attention on the role of the Interplanetary Magnetic Field (IMF) Bz oscillation frequency. The interplanetary conditions and the magnetosphere state have been also visited to investigate recurrent events that produce recurrent geomagnetic storms or activities [17] [18]. In this work, the recurrent activity frequency is carried out during the solar cycles 21 and 22. The seasonal and the solar cycle phases dependence of the foF2 diurnal variation under the recurrent activity are investigated.
Section 2 concerns materials and methods. Section 3 is devoted to results and discussions. Finally, we conclude by presenting the main results and highlighting the research perspectives.
2. Materials and Methods
The storm effect on ionosphere or ionospheric storm is associated with geomagnetic storm [19] [20]. It is well-known that geomagnetic storms show solar cycle phase and seasonal dependence [21] [22]. Therefore, we focus our intention on how the ionosphere F2 region of the African Equatorial Ionization Anomaly (EIA) sector reacts to the geomagnetic activity and principally reacts to the recurrent activity? We consider for our investigation, the solar cycle phases and the seasons dependences and analyse the profile with respect to the classification of Fayot and Vila [23].
2.1. The Criteria for Determining the Solar Cycle Phases
For the solar cycle phases determination, we use the following criteria [24] : 1) minimum phase: Rz < 20; 2) increasing phase: 20 ≤ Rz ≤ 100 and Rz greater than the previous year’s value; 3) maximum phase: Rz >100 [for weak solar cycles (solar cycles with sunspot number maximum (Rzmax) less than 100) the maximum phase is obtained by considering Rz > 0.8 * Rzmax]; and 4) decreasing phase: 100 ≥ Rz ≥ 20 and Rz less than the previous year’s value. In these previous inequations, Rz is the yearly average Zürich sunspot number.
2.2. The Criteria for Determining the Seasons
As many researchers [9] [10] [22] found seasonal dependence of F2 layer during geomagnetic storm, we examine the seasonal effects on the foF2 time profiles under the recurrent activity. The seasons are classified as follows: winter (December, January and February), spring (March, April, May), summer (June, July, August) and autumn (September, October and November).
2.3. The Method for Determining the Recurrent Activity
The recurrent event is one of the three solar events (High speed solar wind coming from solar coronal hole, CMEs and fluctuating solar wind speed due to the fluctuation of the solar neutral sheet) that are able to provoke the geomagnetic storm (a phenomenology of a middle- and low-latitude-geomagnetic variations and quantified by the disturbance storm time (Dst) index [24]. For studying the geomagnetic storm, we use a pixel diagrams as done by Legrand and Simon [2] ; Gyébré et al. [15] and the references with this method therein. A pixel diagram is carried out by selecting the geomagnetic data as a function of the solar activity as described by solar rotation (27 days) [2]. We do not describe the method used for getting a pixel diagram but suggest to the readers to detailed the works of Ouattara and Amory Mazaudier [14] and Gyébré et al. [15]. As in the present paper, only are interested the geomagnetic storms due to recurrent activity, we describe the method used to determine by means of a pixel diagram the geomagnetic storms generated by these activities. Keeping in mind that a pixel diagram (Figure 1) is an adopted colour codes that help to define a geomagnetic
Figure 1. Recurrent activity days shown in the pixel diagram of year 1983.
activity intensity. According to Legrand and Simon [2] and Ouattara and Amory Mazaudier [14] the recurrent activities are shown by several days (more than one) with merging or not orange, red and olive red colours during two or more Bartels’ rotations. These colours correspond to a daily aa (Aa) values superior or equal to 40 nT. By using the pixel diagrams of the solar cycles 21 and 22, we have 173 recurrent days.
2.4. The Method for Analyzing the Data
Our data will be analysed into three ways: the first one is the electrodynamic point of view. In that case, the storm foF2 profiles are analysed by comparing these profiles to those of a five typical foF2 time profiles in African EIA (Equatorial Ionization Anomaly) sector [the noon bite out profile or “B” profile expresses by two maximum peaks with a trough around midday in foF2 time profile, the morning peak profile or “M” profile shown by a presence of a peak in the foF2 profile before midday, the dome profile or “D” profile shown by a maximum peak around midday, the plateau profile or “P” profile shown by the constant values of foF2 during two or more consecutive hours. In that case midday is included and the reverse profile or “R” profile where foF2 profile presents a peak after noon, [23] ]. These profiles have been recorded to the equatorial ionosphere electric currents (equatorial electrojet and equatorial counter electrojet) strength, presence or absence, by reference to the electric current day-to-day time variation under the quiet time condition [25] [26].
The second one is the qualitative appreciation of the storm effects. Therefore, storm time foF2 and quiet time foF2 are plotted together and the deviation observed in storm foF2 with respect to quiet foF2 induces the storm impacts. The storm effects in foF2 time variation is appreciated by showing error bars (The error bars applied are carried out by means of
where the variance V is defined by
with
mean value and N the total number of available data). With respect to error bars, the storm impacts are estimated in term of positive or negative storm. For their definitions see [19] [21] [22] and the all references therein.
The third one is the estimation of the . For the definition of the , we follow that of Vijaya Lekshmi et al. [22] by using the storm time deviation
. But here,
is defined as follows:
where foF2 is critical frequency value of F2 layer. According to these authors the is the maximum positive value of
for the positive storm and the maximum negative value of
for the negative storm.
3. Results and Discussions
Figure 2 highlights the occurrence of the recurrent activity. The panel a concerns the solar cycle phases dependence and the panel b that of the seasons.
Figure 2. Recurrent activity occurrence variability during solar cycle phases (panel (a)) and seasons (panel (b)).
It can be seen from this figure that the recurrent activity more occurs during the solar decreasing phase with 71.67% of the global activity. This result has been previously noted by Zerbo et al. [27]. This situation can be explained by the fact that during the solar cycle decreasing phase, it emanates from the Sun coronal holes the high-speed solar wind streams responsible for the formation of the Corotating Interaction Regions (CIRs) by interacting with slow solar wind [18] and constitute the sources of the recurrent activity [2]. Also the number of solar active events such as solar flares, CMEs, etc., increase seriously during the decreasing phase of a cycle. The panel b shows that there is more recurrent activity during spring month with the occurrence of 41.04%. This result expresses the equinoctial asymmetry of the seasonal occurrence of the recurrent activity.
Whatever the solar cycle phase it can be seen in Figure 3 that storm time profiles and quiet time profiles show the same behaviour during daytime. As here, the time profile shows a statistical time variation of foF2, the analysis of the smoothing steps in foF2 profiles is out of the scoop of this paper because it is not a case study. For analysing storm effects on foF2 time profile, we will focus our attention on ExB drifts because on one hand, foF2 time profile expresses the signature of the ExB [28] [29] and on the other hand, according to Fejer [30] during storm time, ExB drifts are affected by 1) the prompt penetration of magnetospheric convection electric fields; 2) the longer-lived dynamo electric fields [due to the disturbance neutral winds] and 3) storm related changes in ionospheric conductivity [30]. Buonsanto [31] shows that at daytime, during storm time, the prompt penetration of magnetospheric convection electric fields induces the upward vertical drift perturbation and the disturbance dynamo provokes the nearly opposite downward vertical drift perturbation. At daytime, based on the same type of foF2 profile (a noon bite out profile) observed during
Figure 3. Solar cycle phase impacts on foF2 diurnal variation under quiet activity (solid curve) and recurrent activity (dashed curve). The panel (a)-(c) and (d) concerns the solar minimum, increasing maximum and decreasing phase, respectively.
quiet time and storm time, it appears that the above two mechanisms produce the opposite effects on foF2 time profile. Consequently, it seems to appear that the quiet time equatorial F2 region electrodynamic is not affected by the recurrent activity.
At nighttime during solar increasing and decreasing phases the storm profiles show a night time peak that expresses the signature of the reversal electric field in this latitude (Fejer, 1981 and Farley et al., 1986). It can be deduced from this result that recurrent activity induces the electrodynamic process that reverses the electric field at night time in this latitude during all solar cycle phases except for during the solar cycle decreasing phase.
With respect the error bars shown in quiet time graph of each panel of Figure 3, we can assert that in general at daytime (0800 LT - 1600 LT), night time (2000 LT - 2400 LT) and before sunrise (0000 LT - 0300 LT) recurrent activity causes positive storm [storm time foF2 values are superior to those of quiet time [32] ] which is produced at this latitude by the thermospheric composition changes [19] [22]. According to Prölss and Jung [33] and Balan et al. [34] the mechanisms that produce a positive storm in low and mid latitudes are the recombination processes and the downward diffusion of the plasma by the mechanical effects of the storm-time equatorward neutral winds. It can be added to these above mechanisms the enhanced eastward prompt penetration electric fields [35] [36]. Vijaya Lekshmi et al. [22] pointed out that, on one hand, only neutral winds can produce the positive storm at low latitude and on the other hand, the winds and the eastward prompt penetration electric fields together are able to produce positive storms at low and mid-latitudes. A positive storm can be also explained by F2-layers uplifting which is due to EXB drift-induced [37]. By considering the same behaviour of foF2 time profiles, we can assert at this station, the positive storm is produced by thermospheric composition changes. It can be noted that Gyébré et al. [15] by studying CMEs impact on F2-layer at Ouagadougou station, show that the storms due to CMEs also provoke positive storm. But the main difference between CMEs storms and recurrent storms impact is that CMEs storms modify F2-layer quiet time electrodynamic by producing positive and negative storms.
Figure 4 treats the diurnal variation of foF2 during all seasons under quiet and recurrent activities.
At daytime, except summer season where around noon foF2 storm time profile shows a peak which modifies the signature of EXB (it consists of producing a trough around midday in foF2 quiet time profile), the recurrent activity does not modify the quiet time electrodynamic processes because both quiet time and disturbed time profiles show the same behavior. At night time, we observe in the storm time foF2 time profile a peak that expresses the signature of the reversal electric field at 2100 LT during winter (panel a), 2200 LT during autumn (panel d) and 2300 LT during summer (panel b) and spring (panel c) of Figure 4, respectively.
By taking account the error bars, it can be retained that recurrent activity impact is observed at night time. In general, a positive storm is observed after 2200 LT and between 0000 LT and 0200 LT. This impact is more pronounced during summer. This shows the equinoctial asymmetry of the storm action.
When we analyze Figure 3 and Figure 4, one can assert that:
For the solar cycle phase dependence (Figure 3), we have:
1)
;
2)
;
and
3)
.
For the seasonal dependence (Figure 4), we can note that:
1)
;
2)
;
and
3)
.
The above solar cycle phase and seasonal dependence can be seen in Table 1.
Figure 4. Seasonal impacts on foF2 diurnal variation under quiet activity (solid curve) and recurrent activity (dotted curve). The panel (a)-(c) and (d) concerns winter, summer, spring and autumn season, respectively.
Table 1. The solar cycle phases and seasonal dependence and seasonal.
Table 1(a) shows that for solar cycle dependence, the maximum strength occurs during the solar increasing phase and for seasonal dependence, the maximum occurs during summer season (see Table 1(b)).
4. Conclusions
The occurrence of the storm shows that recurrent storm mostly occurs during solar decreasing phase and during spring month.
The analysis of the foF2 profile under recurrent and quiet activities at Ouagadougou station shows that, at daytime, the recurrent activity does not modify the quiet time electrodynamic of F2-layer at this station but induces the thermospheric composition changes. The recurrent activity produces a positive storm during each season and during each solar cycle phase. For solar cycle phases dependence, the present study points out that:
1)
;
2)
;
and
3)
;
For seasonal dependence, it can be retained that:
1)
;
2)
;
and
3)
.